[1] | 1 | ! |
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| 2 | ! $Id: ppm3d.F 1403 2010-07-01 09:02:53Z fairhead $ |
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| 3 | ! |
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| 4 | |
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| 5 | cFrom lin@explorer.gsfc.nasa.gov Wed Apr 15 17:44:44 1998 |
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| 6 | cDate: Wed, 15 Apr 1998 11:37:03 -0400 |
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| 7 | cFrom: lin@explorer.gsfc.nasa.gov |
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| 8 | cTo: Frederic.Hourdin@lmd.jussieu.fr |
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| 9 | cSubject: 3D transport module of the GSFC CTM and GEOS GCM |
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| 10 | |
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| 11 | |
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| 12 | cThis code is sent to you by S-J Lin, DAO, NASA-GSFC |
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| 13 | |
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| 14 | cNote: this version is intended for machines like CRAY |
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| 15 | C-90. No multitasking directives implemented. |
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| 16 | |
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| 17 | |
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| 18 | C ******************************************************************** |
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| 19 | C |
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| 20 | C TransPort Core for Goddard Chemistry Transport Model (G-CTM), Goddard |
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| 21 | C Earth Observing System General Circulation Model (GEOS-GCM), and Data |
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| 22 | C Assimilation System (GEOS-DAS). |
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| 23 | C |
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| 24 | C ******************************************************************** |
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| 25 | C |
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| 26 | C Purpose: given horizontal winds on a hybrid sigma-p surfaces, |
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| 27 | C one call to tpcore updates the 3-D mixing ratio |
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| 28 | C fields one time step (NDT). [vertical mass flux is computed |
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| 29 | C internally consistent with the discretized hydrostatic mass |
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| 30 | C continuity equation of the C-Grid GEOS-GCM (for IGD=1)]. |
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| 31 | C |
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| 32 | C Schemes: Multi-dimensional Flux Form Semi-Lagrangian (FFSL) scheme based |
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| 33 | C on the van Leer or PPM. |
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| 34 | C (see Lin and Rood 1996). |
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| 35 | C Version 4.5 |
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| 36 | C Last modified: Dec. 5, 1996 |
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| 37 | C Major changes from version 4.0: a more general vertical hybrid sigma- |
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| 38 | C pressure coordinate. |
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| 39 | C Subroutines modified: xtp, ytp, fzppm, qckxyz |
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| 40 | C Subroutines deleted: vanz |
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| 41 | C |
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| 42 | C Author: Shian-Jiann Lin |
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| 43 | C mail address: |
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| 44 | C Shian-Jiann Lin* |
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| 45 | C Code 910.3, NASA/GSFC, Greenbelt, MD 20771 |
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| 46 | C Phone: 301-286-9540 |
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| 47 | C E-mail: lin@dao.gsfc.nasa.gov |
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| 48 | C |
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| 49 | C *affiliation: |
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| 50 | C Joint Center for Earth Systems Technology |
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| 51 | C The University of Maryland Baltimore County |
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| 52 | C NASA - Goddard Space Flight Center |
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| 53 | C References: |
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| 54 | C |
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| 55 | C 1. Lin, S.-J., and R. B. Rood, 1996: Multidimensional flux form semi- |
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| 56 | C Lagrangian transport schemes. Mon. Wea. Rev., 124, 2046-2070. |
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| 57 | C |
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| 58 | C 2. Lin, S.-J., W. C. Chao, Y. C. Sud, and G. K. Walker, 1994: A class of |
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| 59 | C the van Leer-type transport schemes and its applications to the moist- |
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| 60 | C ure transport in a General Circulation Model. Mon. Wea. Rev., 122, |
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| 61 | C 1575-1593. |
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| 62 | C |
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| 63 | C ****6***0*********0*********0*********0*********0*********0**********72 |
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| 64 | C |
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| 65 | subroutine ppm3d(IGD,Q,PS1,PS2,U,V,W,NDT,IORD,JORD,KORD,NC,IMR, |
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| 66 | & JNP,j1,NLAY,AP,BP,PT,AE,fill,dum,Umax) |
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| 67 | |
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| 68 | c implicit none |
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| 69 | |
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| 70 | c rajout de déclarations |
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| 71 | c integer Jmax,kmax,ndt0,nstep,k,j,i,ic,l,js,jn,imh,iad,jad,krd |
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| 72 | c integer iu,iiu,j2,jmr,js0,jt |
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| 73 | c real dtdy,dtdy5,rcap,iml,jn0,imjm,pi,dl,dp |
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| 74 | c real dt,cr1,maxdt,ztc,d5,sum1,sum2,ru |
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| 75 | C |
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| 76 | C ******************************************************************** |
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| 77 | C |
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| 78 | C ============= |
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| 79 | C INPUT: |
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| 80 | C ============= |
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| 81 | C |
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| 82 | C Q(IMR,JNP,NLAY,NC): mixing ratios at current time (t) |
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| 83 | C NC: total # of constituents |
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| 84 | C IMR: first dimension (E-W); # of Grid intervals in E-W is IMR |
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| 85 | C JNP: 2nd dimension (N-S); # of Grid intervals in N-S is JNP-1 |
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| 86 | C NLAY: 3rd dimension (# of layers); vertical index increases from 1 at |
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| 87 | C the model top to NLAY near the surface (see fig. below). |
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| 88 | C It is assumed that 6 <= NLAY <= JNP (for dynamic memory allocation) |
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| 89 | C |
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| 90 | C PS1(IMR,JNP): surface pressure at current time (t) |
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| 91 | C PS2(IMR,JNP): surface pressure at mid-time-level (t+NDT/2) |
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| 92 | C PS2 is replaced by the predicted PS (at t+NDT) on output. |
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| 93 | C Note: surface pressure can have any unit or can be multiplied by any |
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| 94 | C const. |
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| 95 | C |
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| 96 | C The pressure at layer edges are defined as follows: |
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| 97 | C |
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| 98 | C p(i,j,k) = AP(k)*PT + BP(k)*PS(i,j) (1) |
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| 99 | C |
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| 100 | C Where PT is a constant having the same unit as PS. |
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| 101 | C AP and BP are unitless constants given at layer edges |
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| 102 | C defining the vertical coordinate. |
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| 103 | C BP(1) = 0., BP(NLAY+1) = 1. |
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| 104 | C The pressure at the model top is PTOP = AP(1)*PT |
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| 105 | C |
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| 106 | C For pure sigma system set AP(k) = 1 for all k, PT = PTOP, |
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| 107 | C BP(k) = sige(k) (sigma at edges), PS = Psfc - PTOP. |
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| 108 | C |
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| 109 | C Note: the sigma-P coordinate is a subset of Eq. 1, which in turn |
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| 110 | C is a subset of the following even more general sigma-P-thelta coord. |
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| 111 | C currently under development. |
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| 112 | C p(i,j,k) = (AP(k)*PT + BP(k)*PS(i,j))/(D(k)-C(k)*TE**(-1/kapa)) |
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| 113 | C |
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| 114 | C ///////////////////////////////// |
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| 115 | C / \ ------------- PTOP -------------- AP(1), BP(1) |
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| 116 | C | |
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| 117 | C delp(1) | ........... Q(i,j,1) ............ |
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| 118 | C | |
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| 119 | C W(1) \ / --------------------------------- AP(2), BP(2) |
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| 120 | C |
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| 121 | C |
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| 122 | C |
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| 123 | C W(k-1) / \ --------------------------------- AP(k), BP(k) |
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| 124 | C | |
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| 125 | C delp(K) | ........... Q(i,j,k) ............ |
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| 126 | C | |
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| 127 | C W(k) \ / --------------------------------- AP(k+1), BP(k+1) |
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| 128 | C |
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| 129 | C |
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| 130 | C |
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| 131 | C / \ --------------------------------- AP(NLAY), BP(NLAY) |
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| 132 | C | |
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| 133 | C delp(NLAY) | ........... Q(i,j,NLAY) ......... |
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| 134 | C | |
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| 135 | C W(NLAY)=0 \ / ------------- surface ----------- AP(NLAY+1), BP(NLAY+1) |
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| 136 | C ////////////////////////////////// |
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| 137 | C |
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| 138 | C U(IMR,JNP,NLAY) & V(IMR,JNP,NLAY):winds (m/s) at mid-time-level (t+NDT/2) |
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| 139 | C U and V may need to be polar filtered in advance in some cases. |
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| 140 | C |
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| 141 | C IGD: grid type on which winds are defined. |
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| 142 | C IGD = 0: A-Grid [all variables defined at the same point from south |
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| 143 | C pole (j=1) to north pole (j=JNP) ] |
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| 144 | C |
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| 145 | C IGD = 1 GEOS-GCM C-Grid |
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| 146 | C [North] |
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| 147 | C |
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| 148 | C V(i,j) |
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| 149 | C | |
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| 150 | C | |
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| 151 | C | |
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| 152 | C U(i-1,j)---Q(i,j)---U(i,j) [EAST] |
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| 153 | C | |
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| 154 | C | |
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| 155 | C | |
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| 156 | C V(i,j-1) |
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| 157 | C |
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| 158 | C U(i, 1) is defined at South Pole. |
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| 159 | C V(i, 1) is half grid north of the South Pole. |
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| 160 | C V(i,JMR) is half grid south of the North Pole. |
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| 161 | C |
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| 162 | C V must be defined at j=1 and j=JMR if IGD=1 |
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| 163 | C V at JNP need not be given. |
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| 164 | C |
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| 165 | C NDT: time step in seconds (need not be constant during the course of |
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| 166 | C the integration). Suggested value: 30 min. for 4x5, 15 min. for 2x2.5 |
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| 167 | C (Lat-Lon) resolution. Smaller values are recommanded if the model |
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| 168 | C has a well-resolved stratosphere. |
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| 169 | C |
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| 170 | C J1 defines the size of the polar cap: |
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| 171 | C South polar cap edge is located at -90 + (j1-1.5)*180/(JNP-1) deg. |
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| 172 | C North polar cap edge is located at 90 - (j1-1.5)*180/(JNP-1) deg. |
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| 173 | C There are currently only two choices (j1=2 or 3). |
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| 174 | C IMR must be an even integer if j1 = 2. Recommended value: J1=3. |
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| 175 | C |
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| 176 | C IORD, JORD, and KORD are integers controlling various options in E-W, N-S, |
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| 177 | C and vertical transport, respectively. Recommended values for positive |
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| 178 | C definite scalars: IORD=JORD=3, KORD=5. Use KORD=3 for non- |
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| 179 | C positive definite scalars or when linear correlation between constituents |
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| 180 | C is to be maintained. |
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| 181 | C |
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| 182 | C _ORD= |
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| 183 | C 1: 1st order upstream scheme (too diffusive, not a useful option; it |
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| 184 | C can be used for debugging purposes; this is THE only known "linear" |
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| 185 | C monotonic advection scheme.). |
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| 186 | C 2: 2nd order van Leer (full monotonicity constraint; |
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| 187 | C see Lin et al 1994, MWR) |
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| 188 | C 3: monotonic PPM* (slightly improved PPM of Collela & Woodward 1984) |
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| 189 | C 4: semi-monotonic PPM (same as 3, but overshoots are allowed) |
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| 190 | C 5: positive-definite PPM (constraint on the subgrid distribution is |
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| 191 | C only strong enough to prevent generation of negative values; |
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| 192 | C both overshoots & undershoots are possible). |
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| 193 | C 6: un-constrained PPM (nearly diffusion free; slightly faster but |
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| 194 | C positivity not quaranteed. Use this option only when the fields |
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| 195 | C and winds are very smooth). |
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| 196 | C |
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| 197 | C *PPM: Piece-wise Parabolic Method |
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| 198 | C |
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| 199 | C Note that KORD <=2 options are no longer supported. DO not use option 4 or 5. |
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| 200 | C for non-positive definite scalars (such as Ertel Potential Vorticity). |
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| 201 | C |
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| 202 | C The implicit numerical diffusion decreases as _ORD increases. |
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| 203 | C The last two options (ORDER=5, 6) should only be used when there is |
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| 204 | C significant explicit diffusion (such as a turbulence parameterization). You |
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| 205 | C might get dispersive results otherwise. |
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| 206 | C No filter of any kind is applied to the constituent fields here. |
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| 207 | C |
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| 208 | C AE: Radius of the sphere (meters). |
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| 209 | C Recommended value for the planet earth: 6.371E6 |
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| 210 | C |
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| 211 | C fill(logical): flag to do filling for negatives (see note below). |
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| 212 | C |
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| 213 | C Umax: Estimate (upper limit) of the maximum U-wind speed (m/s). |
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| 214 | C (220 m/s is a good value for troposphere model; 280 m/s otherwise) |
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| 215 | C |
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| 216 | C ============= |
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| 217 | C Output |
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| 218 | C ============= |
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| 219 | C |
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| 220 | C Q: mixing ratios at future time (t+NDT) (original values are over-written) |
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| 221 | C W(NLAY): large-scale vertical mass flux as diagnosed from the hydrostatic |
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| 222 | C relationship. W will have the same unit as PS1 and PS2 (eg, mb). |
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| 223 | C W must be divided by NDT to get the correct mass-flux unit. |
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| 224 | C The vertical Courant number C = W/delp_UPWIND, where delp_UPWIND |
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| 225 | C is the pressure thickness in the "upwind" direction. For example, |
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| 226 | C C(k) = W(k)/delp(k) if W(k) > 0; |
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| 227 | C C(k) = W(k)/delp(k+1) if W(k) < 0. |
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| 228 | C ( W > 0 is downward, ie, toward surface) |
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| 229 | C PS2: predicted PS at t+NDT (original values are over-written) |
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| 230 | C |
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| 231 | C ******************************************************************** |
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| 232 | C NOTES: |
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| 233 | C This forward-in-time upstream-biased transport scheme reduces to |
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| 234 | C the 2nd order center-in-time center-in-space mass continuity eqn. |
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| 235 | C if Q = 1 (constant fields will remain constant). This also ensures |
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| 236 | C that the computed vertical velocity to be identical to GEOS-1 GCM |
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| 237 | C for on-line transport. |
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| 238 | C |
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| 239 | C A larger polar cap is used if j1=3 (recommended for C-Grid winds or when |
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| 240 | C winds are noisy near poles). |
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| 241 | C |
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| 242 | C Flux-Form Semi-Lagrangian transport in the East-West direction is used |
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| 243 | C when and where Courant # is greater than one. |
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| 244 | C |
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| 245 | C The user needs to change the parameter Jmax or Kmax if the resolution |
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| 246 | C is greater than 0.5 deg in N-S or 150 layers in the vertical direction. |
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| 247 | C (this TransPort Core is otherwise resolution independent and can be used |
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| 248 | C as a library routine). |
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| 249 | C |
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| 250 | C PPM is 4th order accurate when grid spacing is uniform (x & y); 3rd |
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| 251 | C order accurate for non-uniform grid (vertical sigma coord.). |
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| 252 | C |
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| 253 | C Time step is limitted only by transport in the meridional direction. |
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| 254 | C (the FFSL scheme is not implemented in the meridional direction). |
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| 255 | C |
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| 256 | C Since only 1-D limiters are applied, negative values could |
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| 257 | C potentially be generated when large time step is used and when the |
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| 258 | C initial fields contain discontinuities. |
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| 259 | C This does not necessarily imply the integration is unstable. |
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| 260 | C These negatives are typically very small. A filling algorithm is |
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| 261 | C activated if the user set "fill" to be true. |
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| 262 | C |
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| 263 | C The van Leer scheme used here is nearly as accurate as the original PPM |
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| 264 | C due to the use of a 4th order accurate reference slope. The PPM imple- |
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| 265 | C mented here is an improvement over the original and is also based on |
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| 266 | C the 4th order reference slope. |
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| 267 | C |
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| 268 | C ****6***0*********0*********0*********0*********0*********0**********72 |
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| 269 | C |
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| 270 | C User modifiable parameters |
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| 271 | C |
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| 272 | parameter (Jmax = 361, kmax = 150) |
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| 273 | C |
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| 274 | C ****6***0*********0*********0*********0*********0*********0**********72 |
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| 275 | C |
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| 276 | C Input-Output arrays |
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| 277 | C |
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| 278 | |
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| 279 | real Q(IMR,JNP,NLAY,NC),PS1(IMR,JNP),PS2(IMR,JNP), |
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| 280 | & U(IMR,JNP,NLAY),V(IMR,JNP,NLAY),AP(NLAY+1), |
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| 281 | & BP(NLAY+1),W(IMR,JNP,NLAY),NDT,val(NLAY),Umax |
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| 282 | integer IGD,IORD,JORD,KORD,NC,IMR,JNP,j1,NLAY,AE |
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| 283 | integer IMRD2 |
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| 284 | real PT |
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| 285 | logical cross, fill, dum |
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| 286 | C |
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| 287 | C Local dynamic arrays |
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| 288 | C |
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| 289 | real CRX(IMR,JNP),CRY(IMR,JNP),xmass(IMR,JNP),ymass(IMR,JNP), |
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| 290 | & fx1(IMR+1),DPI(IMR,JNP,NLAY),delp1(IMR,JNP,NLAY), |
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| 291 | & WK1(IMR,JNP,NLAY),PU(IMR,JNP),PV(IMR,JNP),DC2(IMR,JNP), |
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| 292 | & delp2(IMR,JNP,NLAY),DQ(IMR,JNP,NLAY,NC),VA(IMR,JNP), |
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| 293 | & UA(IMR,JNP),qtmp(-IMR:2*IMR) |
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| 294 | C |
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| 295 | C Local static arrays |
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| 296 | C |
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| 297 | real DTDX(Jmax), DTDX5(Jmax), acosp(Jmax), |
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| 298 | & cosp(Jmax), cose(Jmax), DAP(kmax),DBK(Kmax) |
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| 299 | data NDT0, NSTEP /0, 0/ |
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| 300 | data cross /.true./ |
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| 301 | SAVE DTDY, DTDY5, RCAP, JS0, JN0, IML, |
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| 302 | & DTDX, DTDX5, ACOSP, COSP, COSE, DAP,DBK |
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| 303 | C |
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| 304 | |
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| 305 | JMR = JNP -1 |
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| 306 | IMJM = IMR*JNP |
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| 307 | j2 = JNP - j1 + 1 |
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| 308 | NSTEP = NSTEP + 1 |
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| 309 | C |
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| 310 | C *********** Initialization ********************** |
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| 311 | if(NSTEP.eq.1) then |
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| 312 | c |
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| 313 | write(6,*) '------------------------------------ ' |
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| 314 | write(6,*) 'NASA/GSFC Transport Core Version 4.5' |
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| 315 | write(6,*) '------------------------------------ ' |
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| 316 | c |
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| 317 | WRITE(6,*) 'IMR=',IMR,' JNP=',JNP,' NLAY=',NLAY,' j1=',j1 |
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| 318 | WRITE(6,*) 'NC=',NC,IORD,JORD,KORD,NDT |
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| 319 | C |
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| 320 | C controles sur les parametres |
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| 321 | if(NLAY.LT.6) then |
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| 322 | write(6,*) 'NLAY must be >= 6' |
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| 323 | stop |
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| 324 | endif |
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| 325 | if (JNP.LT.NLAY) then |
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| 326 | write(6,*) 'JNP must be >= NLAY' |
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| 327 | stop |
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| 328 | endif |
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| 329 | IMRD2=mod(IMR,2) |
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| 330 | if (j1.eq.2.and.IMRD2.NE.0) then |
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| 331 | write(6,*) 'if j1=2 IMR must be an even integer' |
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| 332 | stop |
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| 333 | endif |
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| 334 | |
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| 335 | C |
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| 336 | if(Jmax.lt.JNP .or. Kmax.lt.NLAY) then |
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| 337 | write(6,*) 'Jmax or Kmax is too small' |
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| 338 | stop |
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| 339 | endif |
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| 340 | C |
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| 341 | DO k=1,NLAY |
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| 342 | DAP(k) = (AP(k+1) - AP(k))*PT |
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| 343 | DBK(k) = BP(k+1) - BP(k) |
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| 344 | ENDDO |
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| 345 | C |
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| 346 | PI = 4. * ATAN(1.) |
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| 347 | DL = 2.*PI / REAL(IMR) |
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| 348 | DP = PI / REAL(JMR) |
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| 349 | C |
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| 350 | if(IGD.eq.0) then |
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| 351 | C Compute analytic cosine at cell edges |
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| 352 | call cosa(cosp,cose,JNP,PI,DP) |
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| 353 | else |
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| 354 | C Define cosine consistent with GEOS-GCM (using dycore2.0 or later) |
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| 355 | call cosc(cosp,cose,JNP,PI,DP) |
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| 356 | endif |
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| 357 | C |
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| 358 | do 15 J=2,JMR |
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| 359 | 15 acosp(j) = 1. / cosp(j) |
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| 360 | C |
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| 361 | C Inverse of the Scaled polar cap area. |
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| 362 | C |
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| 363 | RCAP = DP / (IMR*(1.-COS((j1-1.5)*DP))) |
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| 364 | acosp(1) = RCAP |
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| 365 | acosp(JNP) = RCAP |
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| 366 | endif |
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| 367 | C |
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| 368 | if(NDT0 .ne. NDT) then |
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| 369 | DT = NDT |
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| 370 | NDT0 = NDT |
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| 371 | |
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| 372 | if(Umax .lt. 180.) then |
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| 373 | write(6,*) 'Umax may be too small!' |
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| 374 | endif |
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| 375 | CR1 = abs(Umax*DT)/(DL*AE) |
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| 376 | MaxDT = DP*AE / abs(Umax) + 0.5 |
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| 377 | write(6,*)'Largest time step for max(V)=',Umax,' is ',MaxDT |
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| 378 | if(MaxDT .lt. abs(NDT)) then |
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| 379 | write(6,*) 'Warning!!! NDT maybe too large!' |
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| 380 | endif |
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| 381 | C |
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| 382 | if(CR1.ge.0.95) then |
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| 383 | JS0 = 0 |
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| 384 | JN0 = 0 |
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| 385 | IML = IMR-2 |
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| 386 | ZTC = 0. |
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| 387 | else |
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| 388 | ZTC = acos(CR1) * (180./PI) |
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| 389 | C |
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| 390 | JS0 = REAL(JMR)*(90.-ZTC)/180. + 2 |
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| 391 | JS0 = max(JS0, J1+1) |
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| 392 | IML = min(6*JS0/(J1-1)+2, 4*IMR/5) |
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| 393 | JN0 = JNP-JS0+1 |
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| 394 | endif |
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| 395 | C |
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| 396 | C |
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| 397 | do J=2,JMR |
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| 398 | DTDX(j) = DT / ( DL*AE*COSP(J) ) |
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| 399 | |
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| 400 | c print*,'dtdx=',dtdx(j) |
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| 401 | DTDX5(j) = 0.5*DTDX(j) |
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| 402 | enddo |
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| 403 | C |
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| 404 | |
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| 405 | DTDY = DT /(AE*DP) |
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| 406 | c print*,'dtdy=',dtdy |
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| 407 | DTDY5 = 0.5*DTDY |
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| 408 | C |
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| 409 | c write(6,*) 'J1=',J1,' J2=', J2 |
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| 410 | endif |
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| 411 | C |
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| 412 | C *********** End Initialization ********************** |
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| 413 | C |
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| 414 | C delp = pressure thickness: the psudo-density in a hydrostatic system. |
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| 415 | do k=1,NLAY |
---|
| 416 | do j=1,JNP |
---|
| 417 | do i=1,IMR |
---|
| 418 | delp1(i,j,k)=DAP(k)+DBK(k)*PS1(i,j) |
---|
| 419 | delp2(i,j,k)=DAP(k)+DBK(k)*PS2(i,j) |
---|
| 420 | enddo |
---|
| 421 | enddo |
---|
| 422 | enddo |
---|
| 423 | |
---|
| 424 | C |
---|
| 425 | if(j1.ne.2) then |
---|
| 426 | DO 40 IC=1,NC |
---|
| 427 | DO 40 L=1,NLAY |
---|
| 428 | DO 40 I=1,IMR |
---|
| 429 | Q(I, 2,L,IC) = Q(I, 1,L,IC) |
---|
| 430 | 40 Q(I,JMR,L,IC) = Q(I,JNP,L,IC) |
---|
| 431 | endif |
---|
| 432 | C |
---|
| 433 | C Compute "tracer density" |
---|
| 434 | DO 550 IC=1,NC |
---|
| 435 | DO 44 k=1,NLAY |
---|
| 436 | DO 44 j=1,JNP |
---|
| 437 | DO 44 i=1,IMR |
---|
| 438 | 44 DQ(i,j,k,IC) = Q(i,j,k,IC)*delp1(i,j,k) |
---|
| 439 | 550 continue |
---|
| 440 | C |
---|
| 441 | do 1500 k=1,NLAY |
---|
| 442 | C |
---|
| 443 | if(IGD.eq.0) then |
---|
| 444 | C Convert winds on A-Grid to Courant # on C-Grid. |
---|
| 445 | call A2C(U(1,1,k),V(1,1,k),IMR,JMR,j1,j2,CRX,CRY,dtdx5,DTDY5) |
---|
| 446 | else |
---|
| 447 | C Convert winds on C-grid to Courant # |
---|
| 448 | do 45 j=j1,j2 |
---|
| 449 | do 45 i=2,IMR |
---|
| 450 | 45 CRX(i,J) = dtdx(j)*U(i-1,j,k) |
---|
| 451 | |
---|
| 452 | C |
---|
| 453 | do 50 j=j1,j2 |
---|
| 454 | 50 CRX(1,J) = dtdx(j)*U(IMR,j,k) |
---|
| 455 | C |
---|
| 456 | do 55 i=1,IMR*JMR |
---|
| 457 | 55 CRY(i,2) = DTDY*V(i,1,k) |
---|
| 458 | endif |
---|
| 459 | C |
---|
| 460 | C Determine JS and JN |
---|
| 461 | JS = j1 |
---|
| 462 | JN = j2 |
---|
| 463 | C |
---|
| 464 | do j=JS0,j1+1,-1 |
---|
| 465 | do i=1,IMR |
---|
| 466 | if(abs(CRX(i,j)).GT.1.) then |
---|
| 467 | JS = j |
---|
| 468 | go to 2222 |
---|
| 469 | endif |
---|
| 470 | enddo |
---|
| 471 | enddo |
---|
| 472 | C |
---|
| 473 | 2222 continue |
---|
| 474 | do j=JN0,j2-1 |
---|
| 475 | do i=1,IMR |
---|
| 476 | if(abs(CRX(i,j)).GT.1.) then |
---|
| 477 | JN = j |
---|
| 478 | go to 2233 |
---|
| 479 | endif |
---|
| 480 | enddo |
---|
| 481 | enddo |
---|
| 482 | 2233 continue |
---|
| 483 | C |
---|
| 484 | if(j1.ne.2) then ! Enlarged polar cap. |
---|
| 485 | do i=1,IMR |
---|
| 486 | DPI(i, 2,k) = 0. |
---|
| 487 | DPI(i,JMR,k) = 0. |
---|
| 488 | enddo |
---|
| 489 | endif |
---|
| 490 | C |
---|
| 491 | C ******* Compute horizontal mass fluxes ************ |
---|
| 492 | C |
---|
| 493 | C N-S component |
---|
| 494 | do j=j1,j2+1 |
---|
| 495 | D5 = 0.5 * COSE(j) |
---|
| 496 | do i=1,IMR |
---|
| 497 | ymass(i,j) = CRY(i,j)*D5*(delp2(i,j,k) + delp2(i,j-1,k)) |
---|
| 498 | enddo |
---|
| 499 | enddo |
---|
| 500 | C |
---|
| 501 | do 95 j=j1,j2 |
---|
| 502 | DO 95 i=1,IMR |
---|
| 503 | 95 DPI(i,j,k) = (ymass(i,j) - ymass(i,j+1)) * acosp(j) |
---|
| 504 | C |
---|
| 505 | C Poles |
---|
| 506 | sum1 = ymass(IMR,j1 ) |
---|
| 507 | sum2 = ymass(IMR,J2+1) |
---|
| 508 | do i=1,IMR-1 |
---|
| 509 | sum1 = sum1 + ymass(i,j1 ) |
---|
| 510 | sum2 = sum2 + ymass(i,J2+1) |
---|
| 511 | enddo |
---|
| 512 | C |
---|
| 513 | sum1 = - sum1 * RCAP |
---|
| 514 | sum2 = sum2 * RCAP |
---|
| 515 | do i=1,IMR |
---|
| 516 | DPI(i, 1,k) = sum1 |
---|
| 517 | DPI(i,JNP,k) = sum2 |
---|
| 518 | enddo |
---|
| 519 | C |
---|
| 520 | C E-W component |
---|
| 521 | C |
---|
| 522 | do j=j1,j2 |
---|
| 523 | do i=2,IMR |
---|
| 524 | PU(i,j) = 0.5 * (delp2(i,j,k) + delp2(i-1,j,k)) |
---|
| 525 | enddo |
---|
| 526 | enddo |
---|
| 527 | C |
---|
| 528 | do j=j1,j2 |
---|
| 529 | PU(1,j) = 0.5 * (delp2(1,j,k) + delp2(IMR,j,k)) |
---|
| 530 | enddo |
---|
| 531 | C |
---|
| 532 | do 110 j=j1,j2 |
---|
| 533 | DO 110 i=1,IMR |
---|
| 534 | 110 xmass(i,j) = PU(i,j)*CRX(i,j) |
---|
| 535 | C |
---|
| 536 | DO 120 j=j1,j2 |
---|
| 537 | DO 120 i=1,IMR-1 |
---|
| 538 | 120 DPI(i,j,k) = DPI(i,j,k) + xmass(i,j) - xmass(i+1,j) |
---|
| 539 | C |
---|
| 540 | DO 130 j=j1,j2 |
---|
| 541 | 130 DPI(IMR,j,k) = DPI(IMR,j,k) + xmass(IMR,j) - xmass(1,j) |
---|
| 542 | C |
---|
| 543 | DO j=j1,j2 |
---|
| 544 | do i=1,IMR-1 |
---|
| 545 | UA(i,j) = 0.5 * (CRX(i,j)+CRX(i+1,j)) |
---|
| 546 | enddo |
---|
| 547 | enddo |
---|
| 548 | C |
---|
| 549 | DO j=j1,j2 |
---|
| 550 | UA(imr,j) = 0.5 * (CRX(imr,j)+CRX(1,j)) |
---|
| 551 | enddo |
---|
| 552 | ccccccccccccccccccccccccccccccccccccccccccccccccccccccc |
---|
| 553 | c Rajouts pour LMDZ.3.3 |
---|
| 554 | ccccccccccccccccccccccccccccccccccccccccccccccccccccccc |
---|
| 555 | do i=1,IMR |
---|
| 556 | do j=1,JNP |
---|
| 557 | VA(i,j)=0. |
---|
| 558 | enddo |
---|
| 559 | enddo |
---|
| 560 | |
---|
| 561 | do i=1,imr*(JMR-1) |
---|
| 562 | VA(i,2) = 0.5*(CRY(i,2)+CRY(i,3)) |
---|
| 563 | enddo |
---|
| 564 | C |
---|
| 565 | if(j1.eq.2) then |
---|
| 566 | IMH = IMR/2 |
---|
| 567 | do i=1,IMH |
---|
| 568 | VA(i, 1) = 0.5*(CRY(i,2)-CRY(i+IMH,2)) |
---|
| 569 | VA(i+IMH, 1) = -VA(i,1) |
---|
| 570 | VA(i, JNP) = 0.5*(CRY(i,JNP)-CRY(i+IMH,JMR)) |
---|
| 571 | VA(i+IMH,JNP) = -VA(i,JNP) |
---|
| 572 | enddo |
---|
| 573 | VA(IMR,1)=VA(1,1) |
---|
| 574 | VA(IMR,JNP)=VA(1,JNP) |
---|
| 575 | endif |
---|
| 576 | C |
---|
| 577 | C ****6***0*********0*********0*********0*********0*********0**********72 |
---|
| 578 | do 1000 IC=1,NC |
---|
| 579 | C |
---|
| 580 | do i=1,IMJM |
---|
| 581 | wk1(i,1,1) = 0. |
---|
| 582 | wk1(i,1,2) = 0. |
---|
| 583 | enddo |
---|
| 584 | C |
---|
| 585 | C E-W advective cross term |
---|
| 586 | do 250 j=J1,J2 |
---|
| 587 | if(J.GT.JS .and. J.LT.JN) GO TO 250 |
---|
| 588 | C |
---|
| 589 | do i=1,IMR |
---|
| 590 | qtmp(i) = q(i,j,k,IC) |
---|
| 591 | enddo |
---|
| 592 | C |
---|
| 593 | do i=-IML,0 |
---|
| 594 | qtmp(i) = q(IMR+i,j,k,IC) |
---|
| 595 | qtmp(IMR+1-i) = q(1-i,j,k,IC) |
---|
| 596 | enddo |
---|
| 597 | C |
---|
| 598 | DO 230 i=1,IMR |
---|
| 599 | iu = UA(i,j) |
---|
| 600 | ru = UA(i,j) - iu |
---|
| 601 | iiu = i-iu |
---|
| 602 | if(UA(i,j).GE.0.) then |
---|
| 603 | wk1(i,j,1) = qtmp(iiu)+ru*(qtmp(iiu-1)-qtmp(iiu)) |
---|
| 604 | else |
---|
| 605 | wk1(i,j,1) = qtmp(iiu)+ru*(qtmp(iiu)-qtmp(iiu+1)) |
---|
| 606 | endif |
---|
| 607 | wk1(i,j,1) = wk1(i,j,1) - qtmp(i) |
---|
| 608 | 230 continue |
---|
| 609 | 250 continue |
---|
| 610 | C |
---|
| 611 | if(JN.ne.0) then |
---|
| 612 | do j=JS+1,JN-1 |
---|
| 613 | C |
---|
| 614 | do i=1,IMR |
---|
| 615 | qtmp(i) = q(i,j,k,IC) |
---|
| 616 | enddo |
---|
| 617 | C |
---|
| 618 | qtmp(0) = q(IMR,J,k,IC) |
---|
| 619 | qtmp(IMR+1) = q( 1,J,k,IC) |
---|
| 620 | C |
---|
| 621 | do i=1,imr |
---|
| 622 | iu = i - UA(i,j) |
---|
| 623 | wk1(i,j,1) = UA(i,j)*(qtmp(iu) - qtmp(iu+1)) |
---|
| 624 | enddo |
---|
| 625 | enddo |
---|
| 626 | endif |
---|
| 627 | C ****6***0*********0*********0*********0*********0*********0**********72 |
---|
| 628 | C Contribution from the N-S advection |
---|
| 629 | do i=1,imr*(j2-j1+1) |
---|
| 630 | JT = REAL(J1) - VA(i,j1) |
---|
| 631 | wk1(i,j1,2) = VA(i,j1) * (q(i,jt,k,IC) - q(i,jt+1,k,IC)) |
---|
| 632 | enddo |
---|
| 633 | C |
---|
| 634 | do i=1,IMJM |
---|
| 635 | wk1(i,1,1) = q(i,1,k,IC) + 0.5*wk1(i,1,1) |
---|
| 636 | wk1(i,1,2) = q(i,1,k,IC) + 0.5*wk1(i,1,2) |
---|
| 637 | enddo |
---|
| 638 | C |
---|
| 639 | if(cross) then |
---|
| 640 | C Add cross terms in the vertical direction. |
---|
| 641 | if(IORD .GE. 2) then |
---|
| 642 | iad = 2 |
---|
| 643 | else |
---|
| 644 | iad = 1 |
---|
| 645 | endif |
---|
| 646 | C |
---|
| 647 | if(JORD .GE. 2) then |
---|
| 648 | jad = 2 |
---|
| 649 | else |
---|
| 650 | jad = 1 |
---|
| 651 | endif |
---|
| 652 | call xadv(IMR,JNP,j1,j2,wk1(1,1,2),UA,JS,JN,IML,DC2,iad) |
---|
| 653 | call yadv(IMR,JNP,j1,j2,wk1(1,1,1),VA,PV,W,jad) |
---|
| 654 | do j=1,JNP |
---|
| 655 | do i=1,IMR |
---|
| 656 | q(i,j,k,IC) = q(i,j,k,IC) + DC2(i,j) + PV(i,j) |
---|
| 657 | enddo |
---|
| 658 | enddo |
---|
| 659 | endif |
---|
| 660 | C |
---|
| 661 | call xtp(IMR,JNP,IML,j1,j2,JN,JS,PU,DQ(1,1,k,IC),wk1(1,1,2) |
---|
| 662 | & ,CRX,fx1,xmass,IORD) |
---|
| 663 | |
---|
| 664 | call ytp(IMR,JNP,j1,j2,acosp,RCAP,DQ(1,1,k,IC),wk1(1,1,1),CRY, |
---|
| 665 | & DC2,ymass,WK1(1,1,3),wk1(1,1,4),WK1(1,1,5),WK1(1,1,6),JORD) |
---|
| 666 | C |
---|
| 667 | 1000 continue |
---|
| 668 | 1500 continue |
---|
| 669 | C |
---|
| 670 | C ******* Compute vertical mass flux (same unit as PS) *********** |
---|
| 671 | C |
---|
| 672 | C 1st step: compute total column mass CONVERGENCE. |
---|
| 673 | C |
---|
| 674 | do 320 j=1,JNP |
---|
| 675 | do 320 i=1,IMR |
---|
| 676 | 320 CRY(i,j) = DPI(i,j,1) |
---|
| 677 | C |
---|
| 678 | do 330 k=2,NLAY |
---|
| 679 | do 330 j=1,JNP |
---|
| 680 | do 330 i=1,IMR |
---|
| 681 | CRY(i,j) = CRY(i,j) + DPI(i,j,k) |
---|
| 682 | 330 continue |
---|
| 683 | C |
---|
| 684 | do 360 j=1,JNP |
---|
| 685 | do 360 i=1,IMR |
---|
| 686 | C |
---|
| 687 | C 2nd step: compute PS2 (PS at n+1) using the hydrostatic assumption. |
---|
| 688 | C Changes (increases) to surface pressure = total column mass convergence |
---|
| 689 | C |
---|
| 690 | PS2(i,j) = PS1(i,j) + CRY(i,j) |
---|
| 691 | C |
---|
| 692 | C 3rd step: compute vertical mass flux from mass conservation principle. |
---|
| 693 | C |
---|
| 694 | W(i,j,1) = DPI(i,j,1) - DBK(1)*CRY(i,j) |
---|
| 695 | W(i,j,NLAY) = 0. |
---|
| 696 | 360 continue |
---|
| 697 | C |
---|
| 698 | do 370 k=2,NLAY-1 |
---|
| 699 | do 370 j=1,JNP |
---|
| 700 | do 370 i=1,IMR |
---|
| 701 | W(i,j,k) = W(i,j,k-1) + DPI(i,j,k) - DBK(k)*CRY(i,j) |
---|
| 702 | 370 continue |
---|
| 703 | C |
---|
| 704 | DO 380 k=1,NLAY |
---|
| 705 | DO 380 j=1,JNP |
---|
| 706 | DO 380 i=1,IMR |
---|
| 707 | delp2(i,j,k) = DAP(k) + DBK(k)*PS2(i,j) |
---|
| 708 | 380 continue |
---|
| 709 | C |
---|
| 710 | KRD = max(3, KORD) |
---|
| 711 | do 4000 IC=1,NC |
---|
| 712 | C |
---|
| 713 | C****6***0*********0*********0*********0*********0*********0**********72 |
---|
| 714 | |
---|
| 715 | call FZPPM(IMR,JNP,NLAY,j1,DQ(1,1,1,IC),W,Q(1,1,1,IC),WK1,DPI, |
---|
| 716 | & DC2,CRX,CRY,PU,PV,xmass,ymass,delp1,KRD) |
---|
| 717 | C |
---|
| 718 | |
---|
| 719 | if(fill) call qckxyz(DQ(1,1,1,IC),DC2,IMR,JNP,NLAY,j1,j2, |
---|
| 720 | & cosp,acosp,.false.,IC,NSTEP) |
---|
| 721 | C |
---|
| 722 | C Recover tracer mixing ratio from "density" using predicted |
---|
| 723 | C "air density" (pressure thickness) at time-level n+1 |
---|
| 724 | C |
---|
| 725 | DO k=1,NLAY |
---|
| 726 | DO j=1,JNP |
---|
| 727 | DO i=1,IMR |
---|
| 728 | Q(i,j,k,IC) = DQ(i,j,k,IC) / delp2(i,j,k) |
---|
| 729 | c print*,'i=',i,'j=',j,'k=',k,'Q(i,j,k,IC)=',Q(i,j,k,IC) |
---|
| 730 | enddo |
---|
| 731 | enddo |
---|
| 732 | enddo |
---|
| 733 | C |
---|
| 734 | if(j1.ne.2) then |
---|
| 735 | DO 400 k=1,NLAY |
---|
| 736 | DO 400 I=1,IMR |
---|
| 737 | c j=1 c'est le pôle Sud, j=JNP c'est le pôle Nord |
---|
| 738 | Q(I, 2,k,IC) = Q(I, 1,k,IC) |
---|
| 739 | Q(I,JMR,k,IC) = Q(I,JNP,k,IC) |
---|
| 740 | 400 CONTINUE |
---|
| 741 | endif |
---|
| 742 | 4000 continue |
---|
| 743 | C |
---|
| 744 | if(j1.ne.2) then |
---|
| 745 | DO 5000 k=1,NLAY |
---|
| 746 | DO 5000 i=1,IMR |
---|
| 747 | W(i, 2,k) = W(i, 1,k) |
---|
| 748 | W(i,JMR,k) = W(i,JNP,k) |
---|
| 749 | 5000 continue |
---|
| 750 | endif |
---|
| 751 | C |
---|
| 752 | RETURN |
---|
| 753 | END |
---|
| 754 | C |
---|
| 755 | C****6***0*********0*********0*********0*********0*********0**********72 |
---|
| 756 | subroutine FZPPM(IMR,JNP,NLAY,j1,DQ,WZ,P,DC,DQDT,AR,AL,A6, |
---|
| 757 | & flux,wk1,wk2,wz2,delp,KORD) |
---|
| 758 | parameter ( kmax = 150 ) |
---|
| 759 | parameter ( R23 = 2./3., R3 = 1./3.) |
---|
| 760 | real WZ(IMR,JNP,NLAY),P(IMR,JNP,NLAY),DC(IMR,JNP,NLAY), |
---|
| 761 | & wk1(IMR,*),delp(IMR,JNP,NLAY),DQ(IMR,JNP,NLAY), |
---|
| 762 | & DQDT(IMR,JNP,NLAY) |
---|
| 763 | C Assuming JNP >= NLAY |
---|
| 764 | real AR(IMR,*),AL(IMR,*),A6(IMR,*),flux(IMR,*),wk2(IMR,*), |
---|
| 765 | & wz2(IMR,*) |
---|
| 766 | C |
---|
| 767 | JMR = JNP - 1 |
---|
| 768 | IMJM = IMR*JNP |
---|
| 769 | NLAYM1 = NLAY - 1 |
---|
| 770 | C |
---|
| 771 | LMT = KORD - 3 |
---|
| 772 | C |
---|
| 773 | C ****6***0*********0*********0*********0*********0*********0**********72 |
---|
| 774 | C Compute DC for PPM |
---|
| 775 | C ****6***0*********0*********0*********0*********0*********0**********72 |
---|
| 776 | C |
---|
| 777 | do 1000 k=1,NLAYM1 |
---|
| 778 | do 1000 i=1,IMJM |
---|
| 779 | DQDT(i,1,k) = P(i,1,k+1) - P(i,1,k) |
---|
| 780 | 1000 continue |
---|
| 781 | C |
---|
| 782 | DO 1220 k=2,NLAYM1 |
---|
| 783 | DO 1220 I=1,IMJM |
---|
| 784 | c0 = delp(i,1,k) / (delp(i,1,k-1)+delp(i,1,k)+delp(i,1,k+1)) |
---|
| 785 | c1 = (delp(i,1,k-1)+0.5*delp(i,1,k))/(delp(i,1,k+1)+delp(i,1,k)) |
---|
| 786 | c2 = (delp(i,1,k+1)+0.5*delp(i,1,k))/(delp(i,1,k-1)+delp(i,1,k)) |
---|
| 787 | tmp = c0*(c1*DQDT(i,1,k) + c2*DQDT(i,1,k-1)) |
---|
| 788 | Qmax = max(P(i,1,k-1),P(i,1,k),P(i,1,k+1)) - P(i,1,k) |
---|
| 789 | Qmin = P(i,1,k) - min(P(i,1,k-1),P(i,1,k),P(i,1,k+1)) |
---|
| 790 | DC(i,1,k) = sign(min(abs(tmp),Qmax,Qmin), tmp) |
---|
| 791 | 1220 CONTINUE |
---|
| 792 | |
---|
| 793 | C |
---|
| 794 | C ****6***0*********0*********0*********0*********0*********0**********72 |
---|
| 795 | C Loop over latitudes (to save memory) |
---|
| 796 | C ****6***0*********0*********0*********0*********0*********0**********72 |
---|
| 797 | C |
---|
| 798 | DO 2000 j=1,JNP |
---|
| 799 | if((j.eq.2 .or. j.eq.JMR) .and. j1.ne.2) goto 2000 |
---|
| 800 | C |
---|
| 801 | DO k=1,NLAY |
---|
| 802 | DO i=1,IMR |
---|
| 803 | wz2(i,k) = WZ(i,j,k) |
---|
| 804 | wk1(i,k) = P(i,j,k) |
---|
| 805 | wk2(i,k) = delp(i,j,k) |
---|
| 806 | flux(i,k) = DC(i,j,k) !this flux is actually the monotone slope |
---|
| 807 | enddo |
---|
| 808 | enddo |
---|
| 809 | C |
---|
| 810 | C****6***0*********0*********0*********0*********0*********0**********72 |
---|
| 811 | C Compute first guesses at cell interfaces |
---|
| 812 | C First guesses are required to be continuous. |
---|
| 813 | C ****6***0*********0*********0*********0*********0*********0**********72 |
---|
| 814 | C |
---|
| 815 | C three-cell parabolic subgrid distribution at model top |
---|
| 816 | C two-cell parabolic with zero gradient subgrid distribution |
---|
| 817 | C at the surface. |
---|
| 818 | C |
---|
| 819 | C First guess top edge value |
---|
| 820 | DO 10 i=1,IMR |
---|
| 821 | C three-cell PPM |
---|
| 822 | C Compute a,b, and c of q = aP**2 + bP + c using cell averages and delp |
---|
| 823 | a = 3.*( DQDT(i,j,2) - DQDT(i,j,1)*(wk2(i,2)+wk2(i,3))/ |
---|
| 824 | & (wk2(i,1)+wk2(i,2)) ) / |
---|
| 825 | & ( (wk2(i,2)+wk2(i,3))*(wk2(i,1)+wk2(i,2)+wk2(i,3)) ) |
---|
| 826 | b = 2.*DQDT(i,j,1)/(wk2(i,1)+wk2(i,2)) - |
---|
| 827 | & R23*a*(2.*wk2(i,1)+wk2(i,2)) |
---|
| 828 | AL(i,1) = wk1(i,1) - wk2(i,1)*(R3*a*wk2(i,1) + 0.5*b) |
---|
| 829 | AL(i,2) = wk2(i,1)*(a*wk2(i,1) + b) + AL(i,1) |
---|
| 830 | C |
---|
| 831 | C Check if change sign |
---|
| 832 | if(wk1(i,1)*AL(i,1).le.0.) then |
---|
| 833 | AL(i,1) = 0. |
---|
| 834 | flux(i,1) = 0. |
---|
| 835 | else |
---|
| 836 | flux(i,1) = wk1(i,1) - AL(i,1) |
---|
| 837 | endif |
---|
| 838 | 10 continue |
---|
| 839 | C |
---|
| 840 | C Bottom |
---|
| 841 | DO 15 i=1,IMR |
---|
| 842 | C 2-cell PPM with zero gradient right at the surface |
---|
| 843 | C |
---|
| 844 | fct = DQDT(i,j,NLAYM1)*wk2(i,NLAY)**2 / |
---|
| 845 | & ( (wk2(i,NLAY)+wk2(i,NLAYM1))*(2.*wk2(i,NLAY)+wk2(i,NLAYM1))) |
---|
| 846 | AR(i,NLAY) = wk1(i,NLAY) + fct |
---|
| 847 | AL(i,NLAY) = wk1(i,NLAY) - (fct+fct) |
---|
| 848 | if(wk1(i,NLAY)*AR(i,NLAY).le.0.) AR(i,NLAY) = 0. |
---|
| 849 | flux(i,NLAY) = AR(i,NLAY) - wk1(i,NLAY) |
---|
| 850 | 15 continue |
---|
| 851 | |
---|
| 852 | C |
---|
| 853 | C****6***0*********0*********0*********0*********0*********0**********72 |
---|
| 854 | C 4th order interpolation in the interior. |
---|
| 855 | C****6***0*********0*********0*********0*********0*********0**********72 |
---|
| 856 | C |
---|
| 857 | DO 14 k=3,NLAYM1 |
---|
| 858 | DO 12 i=1,IMR |
---|
| 859 | c1 = DQDT(i,j,k-1)*wk2(i,k-1) / (wk2(i,k-1)+wk2(i,k)) |
---|
| 860 | c2 = 2. / (wk2(i,k-2)+wk2(i,k-1)+wk2(i,k)+wk2(i,k+1)) |
---|
| 861 | A1 = (wk2(i,k-2)+wk2(i,k-1)) / (2.*wk2(i,k-1)+wk2(i,k)) |
---|
| 862 | A2 = (wk2(i,k )+wk2(i,k+1)) / (2.*wk2(i,k)+wk2(i,k-1)) |
---|
| 863 | AL(i,k) = wk1(i,k-1) + c1 + c2 * |
---|
| 864 | & ( wk2(i,k )*(c1*(A1 - A2)+A2*flux(i,k-1)) - |
---|
| 865 | & wk2(i,k-1)*A1*flux(i,k) ) |
---|
| 866 | C print *,'AL1',i,k, AL(i,k) |
---|
| 867 | 12 CONTINUE |
---|
| 868 | 14 continue |
---|
| 869 | C |
---|
| 870 | do 20 i=1,IMR*NLAYM1 |
---|
| 871 | AR(i,1) = AL(i,2) |
---|
| 872 | C print *,'AR1',i,AR(i,1) |
---|
| 873 | 20 continue |
---|
| 874 | C |
---|
| 875 | do 30 i=1,IMR*NLAY |
---|
| 876 | A6(i,1) = 3.*(wk1(i,1)+wk1(i,1) - (AL(i,1)+AR(i,1))) |
---|
| 877 | C print *,'A61',i,A6(i,1) |
---|
| 878 | 30 continue |
---|
| 879 | C |
---|
| 880 | C****6***0*********0*********0*********0*********0*********0**********72 |
---|
| 881 | C Top & Bot always monotonic |
---|
| 882 | call lmtppm(flux(1,1),A6(1,1),AR(1,1),AL(1,1),wk1(1,1),IMR,0) |
---|
| 883 | call lmtppm(flux(1,NLAY),A6(1,NLAY),AR(1,NLAY),AL(1,NLAY), |
---|
| 884 | & wk1(1,NLAY),IMR,0) |
---|
| 885 | C |
---|
| 886 | C Interior depending on KORD |
---|
| 887 | if(LMT.LE.2) |
---|
| 888 | & call lmtppm(flux(1,2),A6(1,2),AR(1,2),AL(1,2),wk1(1,2), |
---|
| 889 | & IMR*(NLAY-2),LMT) |
---|
| 890 | C |
---|
| 891 | C****6***0*********0*********0*********0*********0*********0**********72 |
---|
| 892 | C |
---|
| 893 | DO 140 i=1,IMR*NLAYM1 |
---|
| 894 | IF(wz2(i,1).GT.0.) then |
---|
| 895 | CM = wz2(i,1) / wk2(i,1) |
---|
| 896 | flux(i,2) = AR(i,1)+0.5*CM*(AL(i,1)-AR(i,1)+A6(i,1)*(1.-R23*CM)) |
---|
| 897 | else |
---|
| 898 | C print *,'test2-0',i,j,wz2(i,1),wk2(i,2) |
---|
| 899 | CP= wz2(i,1) / wk2(i,2) |
---|
| 900 | C print *,'testCP',CP |
---|
| 901 | flux(i,2) = AL(i,2)+0.5*CP*(AL(i,2)-AR(i,2)-A6(i,2)*(1.+R23*CP)) |
---|
| 902 | C print *,'test2',i, AL(i,2),AR(i,2),A6(i,2),R23 |
---|
| 903 | endif |
---|
| 904 | 140 continue |
---|
| 905 | C |
---|
| 906 | DO 250 i=1,IMR*NLAYM1 |
---|
| 907 | flux(i,2) = wz2(i,1) * flux(i,2) |
---|
| 908 | 250 continue |
---|
| 909 | C |
---|
| 910 | do 350 i=1,IMR |
---|
| 911 | DQ(i,j, 1) = DQ(i,j, 1) - flux(i, 2) |
---|
| 912 | DQ(i,j,NLAY) = DQ(i,j,NLAY) + flux(i,NLAY) |
---|
| 913 | 350 continue |
---|
| 914 | C |
---|
| 915 | do 360 k=2,NLAYM1 |
---|
| 916 | do 360 i=1,IMR |
---|
| 917 | 360 DQ(i,j,k) = DQ(i,j,k) + flux(i,k) - flux(i,k+1) |
---|
| 918 | 2000 continue |
---|
| 919 | return |
---|
| 920 | end |
---|
| 921 | C |
---|
| 922 | subroutine xtp(IMR,JNP,IML,j1,j2,JN,JS,PU,DQ,Q,UC, |
---|
| 923 | & fx1,xmass,IORD) |
---|
| 924 | dimension UC(IMR,*),DC(-IML:IMR+IML+1),xmass(IMR,JNP) |
---|
| 925 | & ,fx1(IMR+1),DQ(IMR,JNP),qtmp(-IML:IMR+1+IML) |
---|
| 926 | dimension PU(IMR,JNP),Q(IMR,JNP),ISAVE(IMR) |
---|
| 927 | C |
---|
| 928 | IMP = IMR + 1 |
---|
| 929 | C |
---|
| 930 | C van Leer at high latitudes |
---|
| 931 | jvan = max(1,JNP/18) |
---|
| 932 | j1vl = j1+jvan |
---|
| 933 | j2vl = j2-jvan |
---|
| 934 | C |
---|
| 935 | do 1310 j=j1,j2 |
---|
| 936 | C |
---|
| 937 | do i=1,IMR |
---|
| 938 | qtmp(i) = q(i,j) |
---|
| 939 | enddo |
---|
| 940 | C |
---|
| 941 | if(j.ge.JN .or. j.le.JS) goto 2222 |
---|
| 942 | C ************* Eulerian ********** |
---|
| 943 | C |
---|
| 944 | qtmp(0) = q(IMR,J) |
---|
| 945 | qtmp(-1) = q(IMR-1,J) |
---|
| 946 | qtmp(IMP) = q(1,J) |
---|
| 947 | qtmp(IMP+1) = q(2,J) |
---|
| 948 | C |
---|
| 949 | IF(IORD.eq.1 .or. j.eq.j1. or. j.eq.j2) THEN |
---|
| 950 | DO 1406 i=1,IMR |
---|
| 951 | iu = REAL(i) - uc(i,j) |
---|
| 952 | 1406 fx1(i) = qtmp(iu) |
---|
| 953 | ELSE |
---|
| 954 | call xmist(IMR,IML,Qtmp,DC) |
---|
| 955 | DC(0) = DC(IMR) |
---|
| 956 | C |
---|
| 957 | if(IORD.eq.2 .or. j.le.j1vl .or. j.ge.j2vl) then |
---|
| 958 | DO 1408 i=1,IMR |
---|
| 959 | iu = REAL(i) - uc(i,j) |
---|
| 960 | 1408 fx1(i) = qtmp(iu) + DC(iu)*(sign(1.,uc(i,j))-uc(i,j)) |
---|
| 961 | else |
---|
| 962 | call fxppm(IMR,IML,UC(1,j),Qtmp,DC,fx1,IORD) |
---|
| 963 | endif |
---|
| 964 | C |
---|
| 965 | ENDIF |
---|
| 966 | C |
---|
| 967 | DO 1506 i=1,IMR |
---|
| 968 | 1506 fx1(i) = fx1(i)*xmass(i,j) |
---|
| 969 | C |
---|
| 970 | goto 1309 |
---|
| 971 | C |
---|
| 972 | C ***** Conservative (flux-form) Semi-Lagrangian transport ***** |
---|
| 973 | C |
---|
| 974 | 2222 continue |
---|
| 975 | C |
---|
| 976 | do i=-IML,0 |
---|
| 977 | qtmp(i) = q(IMR+i,j) |
---|
| 978 | qtmp(IMP-i) = q(1-i,j) |
---|
| 979 | enddo |
---|
| 980 | C |
---|
| 981 | IF(IORD.eq.1 .or. j.eq.j1. or. j.eq.j2) THEN |
---|
| 982 | DO 1306 i=1,IMR |
---|
| 983 | itmp = INT(uc(i,j)) |
---|
| 984 | ISAVE(i) = i - itmp |
---|
| 985 | iu = i - uc(i,j) |
---|
| 986 | 1306 fx1(i) = (uc(i,j) - itmp)*qtmp(iu) |
---|
| 987 | ELSE |
---|
| 988 | call xmist(IMR,IML,Qtmp,DC) |
---|
| 989 | C |
---|
| 990 | do i=-IML,0 |
---|
| 991 | DC(i) = DC(IMR+i) |
---|
| 992 | DC(IMP-i) = DC(1-i) |
---|
| 993 | enddo |
---|
| 994 | C |
---|
| 995 | DO 1307 i=1,IMR |
---|
| 996 | itmp = INT(uc(i,j)) |
---|
| 997 | rut = uc(i,j) - itmp |
---|
| 998 | ISAVE(i) = i - itmp |
---|
| 999 | iu = i - uc(i,j) |
---|
| 1000 | 1307 fx1(i) = rut*(qtmp(iu) + DC(iu)*(sign(1.,rut) - rut)) |
---|
| 1001 | ENDIF |
---|
| 1002 | C |
---|
| 1003 | do 1308 i=1,IMR |
---|
| 1004 | IF(uc(i,j).GT.1.) then |
---|
| 1005 | CDIR$ NOVECTOR |
---|
| 1006 | do ist = ISAVE(i),i-1 |
---|
| 1007 | fx1(i) = fx1(i) + qtmp(ist) |
---|
| 1008 | enddo |
---|
| 1009 | elseIF(uc(i,j).LT.-1.) then |
---|
| 1010 | do ist = i,ISAVE(i)-1 |
---|
| 1011 | fx1(i) = fx1(i) - qtmp(ist) |
---|
| 1012 | enddo |
---|
| 1013 | CDIR$ VECTOR |
---|
| 1014 | endif |
---|
| 1015 | 1308 continue |
---|
| 1016 | do i=1,IMR |
---|
| 1017 | fx1(i) = PU(i,j)*fx1(i) |
---|
| 1018 | enddo |
---|
| 1019 | C |
---|
| 1020 | C *************************************** |
---|
| 1021 | C |
---|
| 1022 | 1309 fx1(IMP) = fx1(1) |
---|
| 1023 | DO 1215 i=1,IMR |
---|
| 1024 | 1215 DQ(i,j) = DQ(i,j) + fx1(i)-fx1(i+1) |
---|
| 1025 | C |
---|
| 1026 | C *************************************** |
---|
| 1027 | C |
---|
| 1028 | 1310 continue |
---|
| 1029 | return |
---|
| 1030 | end |
---|
| 1031 | C |
---|
| 1032 | subroutine fxppm(IMR,IML,UT,P,DC,flux,IORD) |
---|
| 1033 | parameter ( R3 = 1./3., R23 = 2./3. ) |
---|
| 1034 | DIMENSION UT(*),flux(*),P(-IML:IMR+IML+1),DC(-IML:IMR+IML+1) |
---|
| 1035 | DIMENSION AR(0:IMR),AL(0:IMR),A6(0:IMR) |
---|
| 1036 | integer LMT |
---|
| 1037 | c logical first |
---|
| 1038 | c data first /.true./ |
---|
| 1039 | c SAVE LMT |
---|
| 1040 | c if(first) then |
---|
| 1041 | C |
---|
| 1042 | C correction calcul de LMT a chaque passage pour pouvoir choisir |
---|
| 1043 | c plusieurs schemas PPM pour differents traceurs |
---|
| 1044 | c IF (IORD.LE.0) then |
---|
| 1045 | c if(IMR.GE.144) then |
---|
| 1046 | c LMT = 0 |
---|
| 1047 | c elseif(IMR.GE.72) then |
---|
| 1048 | c LMT = 1 |
---|
| 1049 | c else |
---|
| 1050 | c LMT = 2 |
---|
| 1051 | c endif |
---|
| 1052 | c else |
---|
| 1053 | c LMT = IORD - 3 |
---|
| 1054 | c endif |
---|
| 1055 | C |
---|
| 1056 | LMT = IORD - 3 |
---|
| 1057 | c write(6,*) 'PPM option in E-W direction = ', LMT |
---|
| 1058 | c first = .false. |
---|
| 1059 | C endif |
---|
| 1060 | C |
---|
| 1061 | DO 10 i=1,IMR |
---|
| 1062 | 10 AL(i) = 0.5*(p(i-1)+p(i)) + (DC(i-1) - DC(i))*R3 |
---|
| 1063 | C |
---|
| 1064 | do 20 i=1,IMR-1 |
---|
| 1065 | 20 AR(i) = AL(i+1) |
---|
| 1066 | AR(IMR) = AL(1) |
---|
| 1067 | C |
---|
| 1068 | do 30 i=1,IMR |
---|
| 1069 | 30 A6(i) = 3.*(p(i)+p(i) - (AL(i)+AR(i))) |
---|
| 1070 | C |
---|
| 1071 | if(LMT.LE.2) call lmtppm(DC(1),A6(1),AR(1),AL(1),P(1),IMR,LMT) |
---|
| 1072 | C |
---|
| 1073 | AL(0) = AL(IMR) |
---|
| 1074 | AR(0) = AR(IMR) |
---|
| 1075 | A6(0) = A6(IMR) |
---|
| 1076 | C |
---|
| 1077 | DO i=1,IMR |
---|
| 1078 | IF(UT(i).GT.0.) then |
---|
| 1079 | flux(i) = AR(i-1) + 0.5*UT(i)*(AL(i-1) - AR(i-1) + |
---|
| 1080 | & A6(i-1)*(1.-R23*UT(i)) ) |
---|
| 1081 | else |
---|
| 1082 | flux(i) = AL(i) - 0.5*UT(i)*(AR(i) - AL(i) + |
---|
| 1083 | & A6(i)*(1.+R23*UT(i))) |
---|
| 1084 | endif |
---|
| 1085 | enddo |
---|
| 1086 | return |
---|
| 1087 | end |
---|
| 1088 | C |
---|
| 1089 | subroutine xmist(IMR,IML,P,DC) |
---|
| 1090 | parameter( R24 = 1./24.) |
---|
| 1091 | dimension P(-IML:IMR+1+IML),DC(-IML:IMR+1+IML) |
---|
| 1092 | C |
---|
| 1093 | do 10 i=1,IMR |
---|
| 1094 | tmp = R24*(8.*(p(i+1) - p(i-1)) + p(i-2) - p(i+2)) |
---|
| 1095 | Pmax = max(P(i-1), p(i), p(i+1)) - p(i) |
---|
| 1096 | Pmin = p(i) - min(P(i-1), p(i), p(i+1)) |
---|
| 1097 | 10 DC(i) = sign(min(abs(tmp),Pmax,Pmin), tmp) |
---|
| 1098 | return |
---|
| 1099 | end |
---|
| 1100 | C |
---|
| 1101 | subroutine ytp(IMR,JNP,j1,j2,acosp,RCAP,DQ,P,VC,DC2 |
---|
| 1102 | & ,ymass,fx,A6,AR,AL,JORD) |
---|
| 1103 | dimension P(IMR,JNP),VC(IMR,JNP),ymass(IMR,JNP) |
---|
| 1104 | & ,DC2(IMR,JNP),DQ(IMR,JNP),acosp(JNP) |
---|
| 1105 | C Work array |
---|
| 1106 | DIMENSION fx(IMR,JNP),AR(IMR,JNP),AL(IMR,JNP),A6(IMR,JNP) |
---|
| 1107 | C |
---|
| 1108 | JMR = JNP - 1 |
---|
| 1109 | len = IMR*(J2-J1+2) |
---|
| 1110 | C |
---|
| 1111 | if(JORD.eq.1) then |
---|
| 1112 | DO 1000 i=1,len |
---|
| 1113 | JT = REAL(J1) - VC(i,J1) |
---|
| 1114 | 1000 fx(i,j1) = p(i,JT) |
---|
| 1115 | else |
---|
| 1116 | |
---|
| 1117 | call ymist(IMR,JNP,j1,P,DC2,4) |
---|
| 1118 | C |
---|
| 1119 | if(JORD.LE.0 .or. JORD.GE.3) then |
---|
| 1120 | |
---|
| 1121 | call fyppm(VC,P,DC2,fx,IMR,JNP,j1,j2,A6,AR,AL,JORD) |
---|
| 1122 | |
---|
| 1123 | else |
---|
| 1124 | DO 1200 i=1,len |
---|
| 1125 | JT = REAL(J1) - VC(i,J1) |
---|
| 1126 | 1200 fx(i,j1) = p(i,JT) + (sign(1.,VC(i,j1))-VC(i,j1))*DC2(i,JT) |
---|
| 1127 | endif |
---|
| 1128 | endif |
---|
| 1129 | C |
---|
| 1130 | DO 1300 i=1,len |
---|
| 1131 | 1300 fx(i,j1) = fx(i,j1)*ymass(i,j1) |
---|
| 1132 | C |
---|
| 1133 | DO 1400 j=j1,j2 |
---|
| 1134 | DO 1400 i=1,IMR |
---|
| 1135 | 1400 DQ(i,j) = DQ(i,j) + (fx(i,j) - fx(i,j+1)) * acosp(j) |
---|
| 1136 | C |
---|
| 1137 | C Poles |
---|
| 1138 | sum1 = fx(IMR,j1 ) |
---|
| 1139 | sum2 = fx(IMR,J2+1) |
---|
| 1140 | do i=1,IMR-1 |
---|
| 1141 | sum1 = sum1 + fx(i,j1 ) |
---|
| 1142 | sum2 = sum2 + fx(i,J2+1) |
---|
| 1143 | enddo |
---|
| 1144 | C |
---|
| 1145 | sum1 = DQ(1, 1) - sum1 * RCAP |
---|
| 1146 | sum2 = DQ(1,JNP) + sum2 * RCAP |
---|
| 1147 | do i=1,IMR |
---|
| 1148 | DQ(i, 1) = sum1 |
---|
| 1149 | DQ(i,JNP) = sum2 |
---|
| 1150 | enddo |
---|
| 1151 | C |
---|
| 1152 | if(j1.ne.2) then |
---|
| 1153 | do i=1,IMR |
---|
| 1154 | DQ(i, 2) = sum1 |
---|
| 1155 | DQ(i,JMR) = sum2 |
---|
| 1156 | enddo |
---|
| 1157 | endif |
---|
| 1158 | C |
---|
| 1159 | return |
---|
| 1160 | end |
---|
| 1161 | C |
---|
| 1162 | subroutine ymist(IMR,JNP,j1,P,DC,ID) |
---|
| 1163 | parameter ( R24 = 1./24. ) |
---|
| 1164 | dimension P(IMR,JNP),DC(IMR,JNP) |
---|
| 1165 | C |
---|
| 1166 | IMH = IMR / 2 |
---|
| 1167 | JMR = JNP - 1 |
---|
| 1168 | IJM3 = IMR*(JMR-3) |
---|
| 1169 | C |
---|
| 1170 | IF(ID.EQ.2) THEN |
---|
| 1171 | do 10 i=1,IMR*(JMR-1) |
---|
| 1172 | tmp = 0.25*(p(i,3) - p(i,1)) |
---|
| 1173 | Pmax = max(p(i,1),p(i,2),p(i,3)) - p(i,2) |
---|
| 1174 | Pmin = p(i,2) - min(p(i,1),p(i,2),p(i,3)) |
---|
| 1175 | DC(i,2) = sign(min(abs(tmp),Pmin,Pmax),tmp) |
---|
| 1176 | 10 CONTINUE |
---|
| 1177 | ELSE |
---|
| 1178 | do 12 i=1,IMH |
---|
| 1179 | C J=2 |
---|
| 1180 | tmp = (8.*(p(i,3) - p(i,1)) + p(i+IMH,2) - p(i,4))*R24 |
---|
| 1181 | Pmax = max(p(i,1),p(i,2),p(i,3)) - p(i,2) |
---|
| 1182 | Pmin = p(i,2) - min(p(i,1),p(i,2),p(i,3)) |
---|
| 1183 | DC(i,2) = sign(min(abs(tmp),Pmin,Pmax),tmp) |
---|
| 1184 | C J=JMR |
---|
| 1185 | tmp=(8.*(p(i,JNP)-p(i,JMR-1))+p(i,JMR-2)-p(i+IMH,JMR))*R24 |
---|
| 1186 | Pmax = max(p(i,JMR-1),p(i,JMR),p(i,JNP)) - p(i,JMR) |
---|
| 1187 | Pmin = p(i,JMR) - min(p(i,JMR-1),p(i,JMR),p(i,JNP)) |
---|
| 1188 | DC(i,JMR) = sign(min(abs(tmp),Pmin,Pmax),tmp) |
---|
| 1189 | 12 CONTINUE |
---|
| 1190 | do 14 i=IMH+1,IMR |
---|
| 1191 | C J=2 |
---|
| 1192 | tmp = (8.*(p(i,3) - p(i,1)) + p(i-IMH,2) - p(i,4))*R24 |
---|
| 1193 | Pmax = max(p(i,1),p(i,2),p(i,3)) - p(i,2) |
---|
| 1194 | Pmin = p(i,2) - min(p(i,1),p(i,2),p(i,3)) |
---|
| 1195 | DC(i,2) = sign(min(abs(tmp),Pmin,Pmax),tmp) |
---|
| 1196 | C J=JMR |
---|
| 1197 | tmp=(8.*(p(i,JNP)-p(i,JMR-1))+p(i,JMR-2)-p(i-IMH,JMR))*R24 |
---|
| 1198 | Pmax = max(p(i,JMR-1),p(i,JMR),p(i,JNP)) - p(i,JMR) |
---|
| 1199 | Pmin = p(i,JMR) - min(p(i,JMR-1),p(i,JMR),p(i,JNP)) |
---|
| 1200 | DC(i,JMR) = sign(min(abs(tmp),Pmin,Pmax),tmp) |
---|
| 1201 | 14 CONTINUE |
---|
| 1202 | C |
---|
| 1203 | do 15 i=1,IJM3 |
---|
| 1204 | tmp = (8.*(p(i,4) - p(i,2)) + p(i,1) - p(i,5))*R24 |
---|
| 1205 | Pmax = max(p(i,2),p(i,3),p(i,4)) - p(i,3) |
---|
| 1206 | Pmin = p(i,3) - min(p(i,2),p(i,3),p(i,4)) |
---|
| 1207 | DC(i,3) = sign(min(abs(tmp),Pmin,Pmax),tmp) |
---|
| 1208 | 15 CONTINUE |
---|
| 1209 | ENDIF |
---|
| 1210 | C |
---|
| 1211 | if(j1.ne.2) then |
---|
| 1212 | do i=1,IMR |
---|
| 1213 | DC(i,1) = 0. |
---|
| 1214 | DC(i,JNP) = 0. |
---|
| 1215 | enddo |
---|
| 1216 | else |
---|
| 1217 | C Determine slopes in polar caps for scalars! |
---|
| 1218 | C |
---|
| 1219 | do 13 i=1,IMH |
---|
| 1220 | C South |
---|
| 1221 | tmp = 0.25*(p(i,2) - p(i+imh,2)) |
---|
| 1222 | Pmax = max(p(i,2),p(i,1), p(i+imh,2)) - p(i,1) |
---|
| 1223 | Pmin = p(i,1) - min(p(i,2),p(i,1), p(i+imh,2)) |
---|
| 1224 | DC(i,1)=sign(min(abs(tmp),Pmax,Pmin),tmp) |
---|
| 1225 | C North. |
---|
| 1226 | tmp = 0.25*(p(i+imh,JMR) - p(i,JMR)) |
---|
| 1227 | Pmax = max(p(i+imh,JMR),p(i,jnp), p(i,JMR)) - p(i,JNP) |
---|
| 1228 | Pmin = p(i,JNP) - min(p(i+imh,JMR),p(i,jnp), p(i,JMR)) |
---|
| 1229 | DC(i,JNP) = sign(min(abs(tmp),Pmax,pmin),tmp) |
---|
| 1230 | 13 continue |
---|
| 1231 | C |
---|
| 1232 | do 25 i=imh+1,IMR |
---|
| 1233 | DC(i, 1) = - DC(i-imh, 1) |
---|
| 1234 | DC(i,JNP) = - DC(i-imh,JNP) |
---|
| 1235 | 25 continue |
---|
| 1236 | endif |
---|
| 1237 | return |
---|
| 1238 | end |
---|
| 1239 | C |
---|
| 1240 | subroutine fyppm(VC,P,DC,flux,IMR,JNP,j1,j2,A6,AR,AL,JORD) |
---|
| 1241 | parameter ( R3 = 1./3., R23 = 2./3. ) |
---|
| 1242 | real VC(IMR,*),flux(IMR,*),P(IMR,*),DC(IMR,*) |
---|
| 1243 | C Local work arrays. |
---|
| 1244 | real AR(IMR,JNP),AL(IMR,JNP),A6(IMR,JNP) |
---|
| 1245 | integer LMT |
---|
| 1246 | c logical first |
---|
| 1247 | C data first /.true./ |
---|
| 1248 | C SAVE LMT |
---|
| 1249 | C |
---|
| 1250 | IMH = IMR / 2 |
---|
| 1251 | JMR = JNP - 1 |
---|
| 1252 | j11 = j1-1 |
---|
| 1253 | IMJM1 = IMR*(J2-J1+2) |
---|
| 1254 | len = IMR*(J2-J1+3) |
---|
| 1255 | C if(first) then |
---|
| 1256 | C IF(JORD.LE.0) then |
---|
| 1257 | C if(JMR.GE.90) then |
---|
| 1258 | C LMT = 0 |
---|
| 1259 | C elseif(JMR.GE.45) then |
---|
| 1260 | C LMT = 1 |
---|
| 1261 | C else |
---|
| 1262 | C LMT = 2 |
---|
| 1263 | C endif |
---|
| 1264 | C else |
---|
| 1265 | C LMT = JORD - 3 |
---|
| 1266 | C endif |
---|
| 1267 | C |
---|
| 1268 | C first = .false. |
---|
| 1269 | C endif |
---|
| 1270 | C |
---|
| 1271 | c modifs pour pouvoir choisir plusieurs schemas PPM |
---|
| 1272 | LMT = JORD - 3 |
---|
| 1273 | C |
---|
| 1274 | DO 10 i=1,IMR*JMR |
---|
| 1275 | AL(i,2) = 0.5*(p(i,1)+p(i,2)) + (DC(i,1) - DC(i,2))*R3 |
---|
| 1276 | AR(i,1) = AL(i,2) |
---|
| 1277 | 10 CONTINUE |
---|
| 1278 | C |
---|
| 1279 | CPoles: |
---|
| 1280 | C |
---|
| 1281 | DO i=1,IMH |
---|
| 1282 | AL(i,1) = AL(i+IMH,2) |
---|
| 1283 | AL(i+IMH,1) = AL(i,2) |
---|
| 1284 | C |
---|
| 1285 | AR(i,JNP) = AR(i+IMH,JMR) |
---|
| 1286 | AR(i+IMH,JNP) = AR(i,JMR) |
---|
| 1287 | ENDDO |
---|
| 1288 | |
---|
| 1289 | ccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccc |
---|
| 1290 | c Rajout pour LMDZ.3.3 |
---|
| 1291 | cccccccccccccccccccccccccccccccccccccccccccccccccccccccccccc |
---|
| 1292 | AR(IMR,1)=AL(1,1) |
---|
| 1293 | AR(IMR,JNP)=AL(1,JNP) |
---|
| 1294 | ccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccc |
---|
| 1295 | |
---|
| 1296 | |
---|
| 1297 | do 30 i=1,len |
---|
| 1298 | 30 A6(i,j11) = 3.*(p(i,j11)+p(i,j11) - (AL(i,j11)+AR(i,j11))) |
---|
| 1299 | C |
---|
| 1300 | if(LMT.le.2) call lmtppm(DC(1,j11),A6(1,j11),AR(1,j11) |
---|
| 1301 | & ,AL(1,j11),P(1,j11),len,LMT) |
---|
| 1302 | C |
---|
| 1303 | |
---|
| 1304 | DO 140 i=1,IMJM1 |
---|
| 1305 | IF(VC(i,j1).GT.0.) then |
---|
| 1306 | flux(i,j1) = AR(i,j11) + 0.5*VC(i,j1)*(AL(i,j11) - AR(i,j11) + |
---|
| 1307 | & A6(i,j11)*(1.-R23*VC(i,j1)) ) |
---|
| 1308 | else |
---|
| 1309 | flux(i,j1) = AL(i,j1) - 0.5*VC(i,j1)*(AR(i,j1) - AL(i,j1) + |
---|
| 1310 | & A6(i,j1)*(1.+R23*VC(i,j1))) |
---|
| 1311 | endif |
---|
| 1312 | 140 continue |
---|
| 1313 | return |
---|
| 1314 | end |
---|
| 1315 | C |
---|
| 1316 | subroutine yadv(IMR,JNP,j1,j2,p,VA,ady,wk,IAD) |
---|
| 1317 | REAL p(IMR,JNP),ady(IMR,JNP),VA(IMR,JNP) |
---|
| 1318 | REAL WK(IMR,-1:JNP+2) |
---|
| 1319 | C |
---|
| 1320 | JMR = JNP-1 |
---|
| 1321 | IMH = IMR/2 |
---|
| 1322 | do j=1,JNP |
---|
| 1323 | do i=1,IMR |
---|
| 1324 | wk(i,j) = p(i,j) |
---|
| 1325 | enddo |
---|
| 1326 | enddo |
---|
| 1327 | C Poles: |
---|
| 1328 | do i=1,IMH |
---|
| 1329 | wk(i, -1) = p(i+IMH,3) |
---|
| 1330 | wk(i+IMH,-1) = p(i,3) |
---|
| 1331 | wk(i, 0) = p(i+IMH,2) |
---|
| 1332 | wk(i+IMH,0) = p(i,2) |
---|
| 1333 | wk(i,JNP+1) = p(i+IMH,JMR) |
---|
| 1334 | wk(i+IMH,JNP+1) = p(i,JMR) |
---|
| 1335 | wk(i,JNP+2) = p(i+IMH,JNP-2) |
---|
| 1336 | wk(i+IMH,JNP+2) = p(i,JNP-2) |
---|
| 1337 | enddo |
---|
| 1338 | c write(*,*) 'toto 1' |
---|
| 1339 | C -------------------------------- |
---|
| 1340 | IF(IAD.eq.2) then |
---|
| 1341 | do j=j1-1,j2+1 |
---|
| 1342 | do i=1,IMR |
---|
| 1343 | c write(*,*) 'avt NINT','i=',i,'j=',j |
---|
| 1344 | JP = NINT(VA(i,j)) |
---|
| 1345 | rv = JP - VA(i,j) |
---|
| 1346 | c write(*,*) 'VA=',VA(i,j), 'JP1=',JP,'rv=',rv |
---|
| 1347 | JP = j - JP |
---|
| 1348 | c write(*,*) 'JP2=',JP |
---|
| 1349 | a1 = 0.5*(wk(i,jp+1)+wk(i,jp-1)) - wk(i,jp) |
---|
| 1350 | b1 = 0.5*(wk(i,jp+1)-wk(i,jp-1)) |
---|
| 1351 | c write(*,*) 'a1=',a1,'b1=',b1 |
---|
| 1352 | ady(i,j) = wk(i,jp) + rv*(a1*rv + b1) - wk(i,j) |
---|
| 1353 | enddo |
---|
| 1354 | enddo |
---|
| 1355 | c write(*,*) 'toto 2' |
---|
| 1356 | C |
---|
| 1357 | ELSEIF(IAD.eq.1) then |
---|
| 1358 | do j=j1-1,j2+1 |
---|
| 1359 | do i=1,imr |
---|
| 1360 | JP = REAL(j)-VA(i,j) |
---|
| 1361 | ady(i,j) = VA(i,j)*(wk(i,jp)-wk(i,jp+1)) |
---|
| 1362 | enddo |
---|
| 1363 | enddo |
---|
| 1364 | ENDIF |
---|
| 1365 | C |
---|
| 1366 | if(j1.ne.2) then |
---|
| 1367 | sum1 = 0. |
---|
| 1368 | sum2 = 0. |
---|
| 1369 | do i=1,imr |
---|
| 1370 | sum1 = sum1 + ady(i,2) |
---|
| 1371 | sum2 = sum2 + ady(i,JMR) |
---|
| 1372 | enddo |
---|
| 1373 | sum1 = sum1 / IMR |
---|
| 1374 | sum2 = sum2 / IMR |
---|
| 1375 | C |
---|
| 1376 | do i=1,imr |
---|
| 1377 | ady(i, 2) = sum1 |
---|
| 1378 | ady(i,JMR) = sum2 |
---|
| 1379 | ady(i, 1) = sum1 |
---|
| 1380 | ady(i,JNP) = sum2 |
---|
| 1381 | enddo |
---|
| 1382 | else |
---|
| 1383 | C Poles: |
---|
| 1384 | sum1 = 0. |
---|
| 1385 | sum2 = 0. |
---|
| 1386 | do i=1,imr |
---|
| 1387 | sum1 = sum1 + ady(i,1) |
---|
| 1388 | sum2 = sum2 + ady(i,JNP) |
---|
| 1389 | enddo |
---|
| 1390 | sum1 = sum1 / IMR |
---|
| 1391 | sum2 = sum2 / IMR |
---|
| 1392 | C |
---|
| 1393 | do i=1,imr |
---|
| 1394 | ady(i, 1) = sum1 |
---|
| 1395 | ady(i,JNP) = sum2 |
---|
| 1396 | enddo |
---|
| 1397 | endif |
---|
| 1398 | C |
---|
| 1399 | return |
---|
| 1400 | end |
---|
| 1401 | C |
---|
| 1402 | subroutine xadv(IMR,JNP,j1,j2,p,UA,JS,JN,IML,adx,IAD) |
---|
| 1403 | REAL p(IMR,JNP),adx(IMR,JNP),qtmp(-IMR:IMR+IMR),UA(IMR,JNP) |
---|
| 1404 | C |
---|
| 1405 | JMR = JNP-1 |
---|
| 1406 | do 1309 j=j1,j2 |
---|
| 1407 | if(J.GT.JS .and. J.LT.JN) GO TO 1309 |
---|
| 1408 | C |
---|
| 1409 | do i=1,IMR |
---|
| 1410 | qtmp(i) = p(i,j) |
---|
| 1411 | enddo |
---|
| 1412 | C |
---|
| 1413 | do i=-IML,0 |
---|
| 1414 | qtmp(i) = p(IMR+i,j) |
---|
| 1415 | qtmp(IMR+1-i) = p(1-i,j) |
---|
| 1416 | enddo |
---|
| 1417 | C |
---|
| 1418 | IF(IAD.eq.2) THEN |
---|
| 1419 | DO i=1,IMR |
---|
| 1420 | IP = NINT(UA(i,j)) |
---|
| 1421 | ru = IP - UA(i,j) |
---|
| 1422 | IP = i - IP |
---|
| 1423 | a1 = 0.5*(qtmp(ip+1)+qtmp(ip-1)) - qtmp(ip) |
---|
| 1424 | b1 = 0.5*(qtmp(ip+1)-qtmp(ip-1)) |
---|
| 1425 | adx(i,j) = qtmp(ip) + ru*(a1*ru + b1) |
---|
| 1426 | enddo |
---|
| 1427 | ELSEIF(IAD.eq.1) then |
---|
| 1428 | DO i=1,IMR |
---|
| 1429 | iu = UA(i,j) |
---|
| 1430 | ru = UA(i,j) - iu |
---|
| 1431 | iiu = i-iu |
---|
| 1432 | if(UA(i,j).GE.0.) then |
---|
| 1433 | adx(i,j) = qtmp(iiu)+ru*(qtmp(iiu-1)-qtmp(iiu)) |
---|
| 1434 | else |
---|
| 1435 | adx(i,j) = qtmp(iiu)+ru*(qtmp(iiu)-qtmp(iiu+1)) |
---|
| 1436 | endif |
---|
| 1437 | enddo |
---|
| 1438 | ENDIF |
---|
| 1439 | C |
---|
| 1440 | do i=1,IMR |
---|
| 1441 | adx(i,j) = adx(i,j) - p(i,j) |
---|
| 1442 | enddo |
---|
| 1443 | 1309 continue |
---|
| 1444 | C |
---|
| 1445 | C Eulerian upwind |
---|
| 1446 | C |
---|
| 1447 | do j=JS+1,JN-1 |
---|
| 1448 | C |
---|
| 1449 | do i=1,IMR |
---|
| 1450 | qtmp(i) = p(i,j) |
---|
| 1451 | enddo |
---|
| 1452 | C |
---|
| 1453 | qtmp(0) = p(IMR,J) |
---|
| 1454 | qtmp(IMR+1) = p(1,J) |
---|
| 1455 | C |
---|
| 1456 | IF(IAD.eq.2) THEN |
---|
| 1457 | qtmp(-1) = p(IMR-1,J) |
---|
| 1458 | qtmp(IMR+2) = p(2,J) |
---|
| 1459 | do i=1,imr |
---|
| 1460 | IP = NINT(UA(i,j)) |
---|
| 1461 | ru = IP - UA(i,j) |
---|
| 1462 | IP = i - IP |
---|
| 1463 | a1 = 0.5*(qtmp(ip+1)+qtmp(ip-1)) - qtmp(ip) |
---|
| 1464 | b1 = 0.5*(qtmp(ip+1)-qtmp(ip-1)) |
---|
| 1465 | adx(i,j) = qtmp(ip)- p(i,j) + ru*(a1*ru + b1) |
---|
| 1466 | enddo |
---|
| 1467 | ELSEIF(IAD.eq.1) then |
---|
| 1468 | C 1st order |
---|
| 1469 | DO i=1,IMR |
---|
| 1470 | IP = i - UA(i,j) |
---|
| 1471 | adx(i,j) = UA(i,j)*(qtmp(ip)-qtmp(ip+1)) |
---|
| 1472 | enddo |
---|
| 1473 | ENDIF |
---|
| 1474 | enddo |
---|
| 1475 | C |
---|
| 1476 | if(j1.ne.2) then |
---|
| 1477 | do i=1,IMR |
---|
| 1478 | adx(i, 2) = 0. |
---|
| 1479 | adx(i,JMR) = 0. |
---|
| 1480 | enddo |
---|
| 1481 | endif |
---|
| 1482 | C set cross term due to x-adv at the poles to zero. |
---|
| 1483 | do i=1,IMR |
---|
| 1484 | adx(i, 1) = 0. |
---|
| 1485 | adx(i,JNP) = 0. |
---|
| 1486 | enddo |
---|
| 1487 | return |
---|
| 1488 | end |
---|
| 1489 | C |
---|
| 1490 | subroutine lmtppm(DC,A6,AR,AL,P,IM,LMT) |
---|
| 1491 | C |
---|
| 1492 | C A6 = CURVATURE OF THE TEST PARABOLA |
---|
| 1493 | C AR = RIGHT EDGE VALUE OF THE TEST PARABOLA |
---|
| 1494 | C AL = LEFT EDGE VALUE OF THE TEST PARABOLA |
---|
| 1495 | C DC = 0.5 * MISMATCH |
---|
| 1496 | C P = CELL-AVERAGED VALUE |
---|
| 1497 | C IM = VECTOR LENGTH |
---|
| 1498 | C |
---|
| 1499 | C OPTIONS: |
---|
| 1500 | C |
---|
| 1501 | C LMT = 0: FULL MONOTONICITY |
---|
| 1502 | C LMT = 1: SEMI-MONOTONIC CONSTRAINT (NO UNDERSHOOTS) |
---|
| 1503 | C LMT = 2: POSITIVE-DEFINITE CONSTRAINT |
---|
| 1504 | C |
---|
| 1505 | parameter ( R12 = 1./12. ) |
---|
| 1506 | dimension A6(IM),AR(IM),AL(IM),P(IM),DC(IM) |
---|
| 1507 | C |
---|
| 1508 | if(LMT.eq.0) then |
---|
| 1509 | C Full constraint |
---|
| 1510 | do 100 i=1,IM |
---|
| 1511 | if(DC(i).eq.0.) then |
---|
| 1512 | AR(i) = p(i) |
---|
| 1513 | AL(i) = p(i) |
---|
| 1514 | A6(i) = 0. |
---|
| 1515 | else |
---|
| 1516 | da1 = AR(i) - AL(i) |
---|
| 1517 | da2 = da1**2 |
---|
| 1518 | A6DA = A6(i)*da1 |
---|
| 1519 | if(A6DA .lt. -da2) then |
---|
| 1520 | A6(i) = 3.*(AL(i)-p(i)) |
---|
| 1521 | AR(i) = AL(i) - A6(i) |
---|
| 1522 | elseif(A6DA .gt. da2) then |
---|
| 1523 | A6(i) = 3.*(AR(i)-p(i)) |
---|
| 1524 | AL(i) = AR(i) - A6(i) |
---|
| 1525 | endif |
---|
| 1526 | endif |
---|
| 1527 | 100 continue |
---|
| 1528 | elseif(LMT.eq.1) then |
---|
| 1529 | C Semi-monotonic constraint |
---|
| 1530 | do 150 i=1,IM |
---|
| 1531 | if(abs(AR(i)-AL(i)) .GE. -A6(i)) go to 150 |
---|
| 1532 | if(p(i).lt.AR(i) .and. p(i).lt.AL(i)) then |
---|
| 1533 | AR(i) = p(i) |
---|
| 1534 | AL(i) = p(i) |
---|
| 1535 | A6(i) = 0. |
---|
| 1536 | elseif(AR(i) .gt. AL(i)) then |
---|
| 1537 | A6(i) = 3.*(AL(i)-p(i)) |
---|
| 1538 | AR(i) = AL(i) - A6(i) |
---|
| 1539 | else |
---|
| 1540 | A6(i) = 3.*(AR(i)-p(i)) |
---|
| 1541 | AL(i) = AR(i) - A6(i) |
---|
| 1542 | endif |
---|
| 1543 | 150 continue |
---|
| 1544 | elseif(LMT.eq.2) then |
---|
| 1545 | do 250 i=1,IM |
---|
| 1546 | if(abs(AR(i)-AL(i)) .GE. -A6(i)) go to 250 |
---|
| 1547 | fmin = p(i) + 0.25*(AR(i)-AL(i))**2/A6(i) + A6(i)*R12 |
---|
| 1548 | if(fmin.ge.0.) go to 250 |
---|
| 1549 | if(p(i).lt.AR(i) .and. p(i).lt.AL(i)) then |
---|
| 1550 | AR(i) = p(i) |
---|
| 1551 | AL(i) = p(i) |
---|
| 1552 | A6(i) = 0. |
---|
| 1553 | elseif(AR(i) .gt. AL(i)) then |
---|
| 1554 | A6(i) = 3.*(AL(i)-p(i)) |
---|
| 1555 | AR(i) = AL(i) - A6(i) |
---|
| 1556 | else |
---|
| 1557 | A6(i) = 3.*(AR(i)-p(i)) |
---|
| 1558 | AL(i) = AR(i) - A6(i) |
---|
| 1559 | endif |
---|
| 1560 | 250 continue |
---|
| 1561 | endif |
---|
| 1562 | return |
---|
| 1563 | end |
---|
| 1564 | C |
---|
| 1565 | subroutine A2C(U,V,IMR,JMR,j1,j2,CRX,CRY,dtdx5,DTDY5) |
---|
| 1566 | dimension U(IMR,*),V(IMR,*),CRX(IMR,*),CRY(IMR,*),DTDX5(*) |
---|
| 1567 | C |
---|
| 1568 | do 35 j=j1,j2 |
---|
| 1569 | do 35 i=2,IMR |
---|
| 1570 | 35 CRX(i,J) = dtdx5(j)*(U(i,j)+U(i-1,j)) |
---|
| 1571 | C |
---|
| 1572 | do 45 j=j1,j2 |
---|
| 1573 | 45 CRX(1,J) = dtdx5(j)*(U(1,j)+U(IMR,j)) |
---|
| 1574 | C |
---|
| 1575 | do 55 i=1,IMR*JMR |
---|
| 1576 | 55 CRY(i,2) = DTDY5*(V(i,2)+V(i,1)) |
---|
| 1577 | return |
---|
| 1578 | end |
---|
| 1579 | C |
---|
| 1580 | subroutine cosa(cosp,cose,JNP,PI,DP) |
---|
| 1581 | dimension cosp(*),cose(*) |
---|
| 1582 | JMR = JNP-1 |
---|
| 1583 | do 55 j=2,JNP |
---|
| 1584 | ph5 = -0.5*PI + (REAL(J-1)-0.5)*DP |
---|
| 1585 | 55 cose(j) = cos(ph5) |
---|
| 1586 | C |
---|
| 1587 | JEQ = (JNP+1) / 2 |
---|
| 1588 | if(JMR .eq. 2*(JMR/2) ) then |
---|
| 1589 | do j=JNP, JEQ+1, -1 |
---|
| 1590 | cose(j) = cose(JNP+2-j) |
---|
| 1591 | enddo |
---|
| 1592 | else |
---|
| 1593 | C cell edge at equator. |
---|
| 1594 | cose(JEQ+1) = 1. |
---|
| 1595 | do j=JNP, JEQ+2, -1 |
---|
| 1596 | cose(j) = cose(JNP+2-j) |
---|
| 1597 | enddo |
---|
| 1598 | endif |
---|
| 1599 | C |
---|
| 1600 | do 66 j=2,JMR |
---|
| 1601 | 66 cosp(j) = 0.5*(cose(j)+cose(j+1)) |
---|
| 1602 | cosp(1) = 0. |
---|
| 1603 | cosp(JNP) = 0. |
---|
| 1604 | return |
---|
| 1605 | end |
---|
| 1606 | C |
---|
| 1607 | subroutine cosc(cosp,cose,JNP,PI,DP) |
---|
| 1608 | dimension cosp(*),cose(*) |
---|
| 1609 | C |
---|
| 1610 | phi = -0.5*PI |
---|
| 1611 | do 55 j=2,JNP-1 |
---|
| 1612 | phi = phi + DP |
---|
| 1613 | 55 cosp(j) = cos(phi) |
---|
| 1614 | cosp( 1) = 0. |
---|
| 1615 | cosp(JNP) = 0. |
---|
| 1616 | C |
---|
| 1617 | do 66 j=2,JNP |
---|
| 1618 | cose(j) = 0.5*(cosp(j)+cosp(j-1)) |
---|
| 1619 | 66 CONTINUE |
---|
| 1620 | C |
---|
| 1621 | do 77 j=2,JNP-1 |
---|
| 1622 | cosp(j) = 0.5*(cose(j)+cose(j+1)) |
---|
| 1623 | 77 CONTINUE |
---|
| 1624 | return |
---|
| 1625 | end |
---|
| 1626 | C |
---|
| 1627 | SUBROUTINE qckxyz (Q,qtmp,IMR,JNP,NLAY,j1,j2,cosp,acosp, |
---|
| 1628 | & cross,IC,NSTEP) |
---|
| 1629 | C |
---|
| 1630 | parameter( tiny = 1.E-60 ) |
---|
| 1631 | DIMENSION Q(IMR,JNP,NLAY),qtmp(IMR,JNP),cosp(*),acosp(*) |
---|
| 1632 | logical cross |
---|
| 1633 | C |
---|
| 1634 | NLAYM1 = NLAY-1 |
---|
| 1635 | len = IMR*(j2-j1+1) |
---|
| 1636 | ip = 0 |
---|
| 1637 | C |
---|
| 1638 | C Top layer |
---|
| 1639 | L = 1 |
---|
| 1640 | icr = 1 |
---|
| 1641 | call filns(q(1,1,L),IMR,JNP,j1,j2,cosp,acosp,ipy,tiny) |
---|
| 1642 | if(ipy.eq.0) goto 50 |
---|
| 1643 | call filew(q(1,1,L),qtmp,IMR,JNP,j1,j2,ipx,tiny) |
---|
| 1644 | if(ipx.eq.0) goto 50 |
---|
| 1645 | C |
---|
| 1646 | if(cross) then |
---|
| 1647 | call filcr(q(1,1,L),IMR,JNP,j1,j2,cosp,acosp,icr,tiny) |
---|
| 1648 | endif |
---|
| 1649 | if(icr.eq.0) goto 50 |
---|
| 1650 | C |
---|
| 1651 | C Vertical filling... |
---|
| 1652 | do i=1,len |
---|
| 1653 | IF( Q(i,j1,1).LT.0.) THEN |
---|
| 1654 | ip = ip + 1 |
---|
| 1655 | Q(i,j1,2) = Q(i,j1,2) + Q(i,j1,1) |
---|
| 1656 | Q(i,j1,1) = 0. |
---|
| 1657 | endif |
---|
| 1658 | enddo |
---|
| 1659 | C |
---|
| 1660 | 50 continue |
---|
| 1661 | DO 225 L = 2,NLAYM1 |
---|
| 1662 | icr = 1 |
---|
| 1663 | C |
---|
| 1664 | call filns(q(1,1,L),IMR,JNP,j1,j2,cosp,acosp,ipy,tiny) |
---|
| 1665 | if(ipy.eq.0) goto 225 |
---|
| 1666 | call filew(q(1,1,L),qtmp,IMR,JNP,j1,j2,ipx,tiny) |
---|
| 1667 | if(ipx.eq.0) go to 225 |
---|
| 1668 | if(cross) then |
---|
| 1669 | call filcr(q(1,1,L),IMR,JNP,j1,j2,cosp,acosp,icr,tiny) |
---|
| 1670 | endif |
---|
| 1671 | if(icr.eq.0) goto 225 |
---|
| 1672 | C |
---|
| 1673 | do i=1,len |
---|
| 1674 | IF( Q(I,j1,L).LT.0.) THEN |
---|
| 1675 | C |
---|
| 1676 | ip = ip + 1 |
---|
| 1677 | C From above |
---|
| 1678 | qup = Q(I,j1,L-1) |
---|
| 1679 | qly = -Q(I,j1,L) |
---|
| 1680 | dup = min(qly,qup) |
---|
| 1681 | Q(I,j1,L-1) = qup - dup |
---|
| 1682 | Q(I,j1,L ) = dup-qly |
---|
| 1683 | C Below |
---|
| 1684 | Q(I,j1,L+1) = Q(I,j1,L+1) + Q(I,j1,L) |
---|
| 1685 | Q(I,j1,L) = 0. |
---|
| 1686 | ENDIF |
---|
| 1687 | ENDDO |
---|
| 1688 | 225 CONTINUE |
---|
| 1689 | C |
---|
| 1690 | C BOTTOM LAYER |
---|
| 1691 | sum = 0. |
---|
| 1692 | L = NLAY |
---|
| 1693 | C |
---|
| 1694 | call filns(q(1,1,L),IMR,JNP,j1,j2,cosp,acosp,ipy,tiny) |
---|
| 1695 | if(ipy.eq.0) goto 911 |
---|
| 1696 | call filew(q(1,1,L),qtmp,IMR,JNP,j1,j2,ipx,tiny) |
---|
| 1697 | if(ipx.eq.0) goto 911 |
---|
| 1698 | C |
---|
| 1699 | call filcr(q(1,1,L),IMR,JNP,j1,j2,cosp,acosp,icr,tiny) |
---|
| 1700 | if(icr.eq.0) goto 911 |
---|
| 1701 | C |
---|
| 1702 | DO I=1,len |
---|
| 1703 | IF( Q(I,j1,L).LT.0.) THEN |
---|
| 1704 | ip = ip + 1 |
---|
| 1705 | c |
---|
| 1706 | C From above |
---|
| 1707 | C |
---|
| 1708 | qup = Q(I,j1,NLAYM1) |
---|
| 1709 | qly = -Q(I,j1,L) |
---|
| 1710 | dup = min(qly,qup) |
---|
| 1711 | Q(I,j1,NLAYM1) = qup - dup |
---|
| 1712 | C From "below" the surface. |
---|
| 1713 | sum = sum + qly-dup |
---|
| 1714 | Q(I,j1,L) = 0. |
---|
| 1715 | ENDIF |
---|
| 1716 | ENDDO |
---|
| 1717 | C |
---|
| 1718 | 911 continue |
---|
| 1719 | C |
---|
| 1720 | if(ip.gt.IMR) then |
---|
| 1721 | write(6,*) 'IC=',IC,' STEP=',NSTEP, |
---|
| 1722 | & ' Vertical filling pts=',ip |
---|
| 1723 | endif |
---|
| 1724 | C |
---|
| 1725 | if(sum.gt.1.e-25) then |
---|
| 1726 | write(6,*) IC,NSTEP,' Mass source from the ground=',sum |
---|
| 1727 | endif |
---|
| 1728 | RETURN |
---|
| 1729 | END |
---|
| 1730 | C |
---|
| 1731 | subroutine filcr(q,IMR,JNP,j1,j2,cosp,acosp,icr,tiny) |
---|
| 1732 | dimension q(IMR,*),cosp(*),acosp(*) |
---|
| 1733 | icr = 0 |
---|
| 1734 | do 65 j=j1+1,j2-1 |
---|
| 1735 | DO 50 i=1,IMR-1 |
---|
| 1736 | IF(q(i,j).LT.0.) THEN |
---|
| 1737 | icr = 1 |
---|
| 1738 | dq = - q(i,j)*cosp(j) |
---|
| 1739 | C N-E |
---|
| 1740 | dn = q(i+1,j+1)*cosp(j+1) |
---|
| 1741 | d0 = max(0.,dn) |
---|
| 1742 | d1 = min(dq,d0) |
---|
| 1743 | q(i+1,j+1) = (dn - d1)*acosp(j+1) |
---|
| 1744 | dq = dq - d1 |
---|
| 1745 | C S-E |
---|
| 1746 | ds = q(i+1,j-1)*cosp(j-1) |
---|
| 1747 | d0 = max(0.,ds) |
---|
| 1748 | d2 = min(dq,d0) |
---|
| 1749 | q(i+1,j-1) = (ds - d2)*acosp(j-1) |
---|
| 1750 | q(i,j) = (d2 - dq)*acosp(j) + tiny |
---|
| 1751 | endif |
---|
| 1752 | 50 continue |
---|
| 1753 | if(icr.eq.0 .and. q(IMR,j).ge.0.) goto 65 |
---|
| 1754 | DO 55 i=2,IMR |
---|
| 1755 | IF(q(i,j).LT.0.) THEN |
---|
| 1756 | icr = 1 |
---|
| 1757 | dq = - q(i,j)*cosp(j) |
---|
| 1758 | C N-W |
---|
| 1759 | dn = q(i-1,j+1)*cosp(j+1) |
---|
| 1760 | d0 = max(0.,dn) |
---|
| 1761 | d1 = min(dq,d0) |
---|
| 1762 | q(i-1,j+1) = (dn - d1)*acosp(j+1) |
---|
| 1763 | dq = dq - d1 |
---|
| 1764 | C S-W |
---|
| 1765 | ds = q(i-1,j-1)*cosp(j-1) |
---|
| 1766 | d0 = max(0.,ds) |
---|
| 1767 | d2 = min(dq,d0) |
---|
| 1768 | q(i-1,j-1) = (ds - d2)*acosp(j-1) |
---|
| 1769 | q(i,j) = (d2 - dq)*acosp(j) + tiny |
---|
| 1770 | endif |
---|
| 1771 | 55 continue |
---|
| 1772 | C ***************************************** |
---|
| 1773 | C i=1 |
---|
| 1774 | i=1 |
---|
| 1775 | IF(q(i,j).LT.0.) THEN |
---|
| 1776 | icr = 1 |
---|
| 1777 | dq = - q(i,j)*cosp(j) |
---|
| 1778 | C N-W |
---|
| 1779 | dn = q(IMR,j+1)*cosp(j+1) |
---|
| 1780 | d0 = max(0.,dn) |
---|
| 1781 | d1 = min(dq,d0) |
---|
| 1782 | q(IMR,j+1) = (dn - d1)*acosp(j+1) |
---|
| 1783 | dq = dq - d1 |
---|
| 1784 | C S-W |
---|
| 1785 | ds = q(IMR,j-1)*cosp(j-1) |
---|
| 1786 | d0 = max(0.,ds) |
---|
| 1787 | d2 = min(dq,d0) |
---|
| 1788 | q(IMR,j-1) = (ds - d2)*acosp(j-1) |
---|
| 1789 | q(i,j) = (d2 - dq)*acosp(j) + tiny |
---|
| 1790 | endif |
---|
| 1791 | C ***************************************** |
---|
| 1792 | C i=IMR |
---|
| 1793 | i=IMR |
---|
| 1794 | IF(q(i,j).LT.0.) THEN |
---|
| 1795 | icr = 1 |
---|
| 1796 | dq = - q(i,j)*cosp(j) |
---|
| 1797 | C N-E |
---|
| 1798 | dn = q(1,j+1)*cosp(j+1) |
---|
| 1799 | d0 = max(0.,dn) |
---|
| 1800 | d1 = min(dq,d0) |
---|
| 1801 | q(1,j+1) = (dn - d1)*acosp(j+1) |
---|
| 1802 | dq = dq - d1 |
---|
| 1803 | C S-E |
---|
| 1804 | ds = q(1,j-1)*cosp(j-1) |
---|
| 1805 | d0 = max(0.,ds) |
---|
| 1806 | d2 = min(dq,d0) |
---|
| 1807 | q(1,j-1) = (ds - d2)*acosp(j-1) |
---|
| 1808 | q(i,j) = (d2 - dq)*acosp(j) + tiny |
---|
| 1809 | endif |
---|
| 1810 | C ***************************************** |
---|
| 1811 | 65 continue |
---|
| 1812 | C |
---|
| 1813 | do i=1,IMR |
---|
| 1814 | if(q(i,j1).lt.0. .or. q(i,j2).lt.0.) then |
---|
| 1815 | icr = 1 |
---|
| 1816 | goto 80 |
---|
| 1817 | endif |
---|
| 1818 | enddo |
---|
| 1819 | C |
---|
| 1820 | 80 continue |
---|
| 1821 | C |
---|
| 1822 | if(q(1,1).lt.0. .or. q(1,jnp).lt.0.) then |
---|
| 1823 | icr = 1 |
---|
| 1824 | endif |
---|
| 1825 | C |
---|
| 1826 | return |
---|
| 1827 | end |
---|
| 1828 | C |
---|
| 1829 | subroutine filns(q,IMR,JNP,j1,j2,cosp,acosp,ipy,tiny) |
---|
| 1830 | dimension q(IMR,*),cosp(*),acosp(*) |
---|
| 1831 | c logical first |
---|
| 1832 | c data first /.true./ |
---|
| 1833 | c save cap1 |
---|
| 1834 | C |
---|
| 1835 | c if(first) then |
---|
| 1836 | DP = 4.*ATAN(1.)/REAL(JNP-1) |
---|
| 1837 | CAP1 = IMR*(1.-COS((j1-1.5)*DP))/DP |
---|
| 1838 | c first = .false. |
---|
| 1839 | c endif |
---|
| 1840 | C |
---|
| 1841 | ipy = 0 |
---|
| 1842 | do 55 j=j1+1,j2-1 |
---|
| 1843 | DO 55 i=1,IMR |
---|
| 1844 | IF(q(i,j).LT.0.) THEN |
---|
| 1845 | ipy = 1 |
---|
| 1846 | dq = - q(i,j)*cosp(j) |
---|
| 1847 | C North |
---|
| 1848 | dn = q(i,j+1)*cosp(j+1) |
---|
| 1849 | d0 = max(0.,dn) |
---|
| 1850 | d1 = min(dq,d0) |
---|
| 1851 | q(i,j+1) = (dn - d1)*acosp(j+1) |
---|
| 1852 | dq = dq - d1 |
---|
| 1853 | C South |
---|
| 1854 | ds = q(i,j-1)*cosp(j-1) |
---|
| 1855 | d0 = max(0.,ds) |
---|
| 1856 | d2 = min(dq,d0) |
---|
| 1857 | q(i,j-1) = (ds - d2)*acosp(j-1) |
---|
| 1858 | q(i,j) = (d2 - dq)*acosp(j) + tiny |
---|
| 1859 | endif |
---|
| 1860 | 55 continue |
---|
| 1861 | C |
---|
| 1862 | do i=1,imr |
---|
| 1863 | IF(q(i,j1).LT.0.) THEN |
---|
| 1864 | ipy = 1 |
---|
| 1865 | dq = - q(i,j1)*cosp(j1) |
---|
| 1866 | C North |
---|
| 1867 | dn = q(i,j1+1)*cosp(j1+1) |
---|
| 1868 | d0 = max(0.,dn) |
---|
| 1869 | d1 = min(dq,d0) |
---|
| 1870 | q(i,j1+1) = (dn - d1)*acosp(j1+1) |
---|
| 1871 | q(i,j1) = (d1 - dq)*acosp(j1) + tiny |
---|
| 1872 | endif |
---|
| 1873 | enddo |
---|
| 1874 | C |
---|
| 1875 | j = j2 |
---|
| 1876 | do i=1,imr |
---|
| 1877 | IF(q(i,j).LT.0.) THEN |
---|
| 1878 | ipy = 1 |
---|
| 1879 | dq = - q(i,j)*cosp(j) |
---|
| 1880 | C South |
---|
| 1881 | ds = q(i,j-1)*cosp(j-1) |
---|
| 1882 | d0 = max(0.,ds) |
---|
| 1883 | d2 = min(dq,d0) |
---|
| 1884 | q(i,j-1) = (ds - d2)*acosp(j-1) |
---|
| 1885 | q(i,j) = (d2 - dq)*acosp(j) + tiny |
---|
| 1886 | endif |
---|
| 1887 | enddo |
---|
| 1888 | C |
---|
| 1889 | C Check Poles. |
---|
| 1890 | if(q(1,1).lt.0.) then |
---|
| 1891 | dq = q(1,1)*cap1/REAL(IMR)*acosp(j1) |
---|
| 1892 | do i=1,imr |
---|
| 1893 | q(i,1) = 0. |
---|
| 1894 | q(i,j1) = q(i,j1) + dq |
---|
| 1895 | if(q(i,j1).lt.0.) ipy = 1 |
---|
| 1896 | enddo |
---|
| 1897 | endif |
---|
| 1898 | C |
---|
| 1899 | if(q(1,JNP).lt.0.) then |
---|
| 1900 | dq = q(1,JNP)*cap1/REAL(IMR)*acosp(j2) |
---|
| 1901 | do i=1,imr |
---|
| 1902 | q(i,JNP) = 0. |
---|
| 1903 | q(i,j2) = q(i,j2) + dq |
---|
| 1904 | if(q(i,j2).lt.0.) ipy = 1 |
---|
| 1905 | enddo |
---|
| 1906 | endif |
---|
| 1907 | C |
---|
| 1908 | return |
---|
| 1909 | end |
---|
| 1910 | C |
---|
| 1911 | subroutine filew(q,qtmp,IMR,JNP,j1,j2,ipx,tiny) |
---|
| 1912 | dimension q(IMR,*),qtmp(JNP,IMR) |
---|
| 1913 | C |
---|
| 1914 | ipx = 0 |
---|
| 1915 | C Copy & swap direction for vectorization. |
---|
| 1916 | do 25 i=1,imr |
---|
| 1917 | do 25 j=j1,j2 |
---|
| 1918 | 25 qtmp(j,i) = q(i,j) |
---|
| 1919 | C |
---|
| 1920 | do 55 i=2,imr-1 |
---|
| 1921 | do 55 j=j1,j2 |
---|
| 1922 | if(qtmp(j,i).lt.0.) then |
---|
| 1923 | ipx = 1 |
---|
| 1924 | c west |
---|
| 1925 | d0 = max(0.,qtmp(j,i-1)) |
---|
| 1926 | d1 = min(-qtmp(j,i),d0) |
---|
| 1927 | qtmp(j,i-1) = qtmp(j,i-1) - d1 |
---|
| 1928 | qtmp(j,i) = qtmp(j,i) + d1 |
---|
| 1929 | c east |
---|
| 1930 | d0 = max(0.,qtmp(j,i+1)) |
---|
| 1931 | d2 = min(-qtmp(j,i),d0) |
---|
| 1932 | qtmp(j,i+1) = qtmp(j,i+1) - d2 |
---|
| 1933 | qtmp(j,i) = qtmp(j,i) + d2 + tiny |
---|
| 1934 | endif |
---|
| 1935 | 55 continue |
---|
| 1936 | c |
---|
| 1937 | i=1 |
---|
| 1938 | do 65 j=j1,j2 |
---|
| 1939 | if(qtmp(j,i).lt.0.) then |
---|
| 1940 | ipx = 1 |
---|
| 1941 | c west |
---|
| 1942 | d0 = max(0.,qtmp(j,imr)) |
---|
| 1943 | d1 = min(-qtmp(j,i),d0) |
---|
| 1944 | qtmp(j,imr) = qtmp(j,imr) - d1 |
---|
| 1945 | qtmp(j,i) = qtmp(j,i) + d1 |
---|
| 1946 | c east |
---|
| 1947 | d0 = max(0.,qtmp(j,i+1)) |
---|
| 1948 | d2 = min(-qtmp(j,i),d0) |
---|
| 1949 | qtmp(j,i+1) = qtmp(j,i+1) - d2 |
---|
| 1950 | c |
---|
| 1951 | qtmp(j,i) = qtmp(j,i) + d2 + tiny |
---|
| 1952 | endif |
---|
| 1953 | 65 continue |
---|
| 1954 | i=IMR |
---|
| 1955 | do 75 j=j1,j2 |
---|
| 1956 | if(qtmp(j,i).lt.0.) then |
---|
| 1957 | ipx = 1 |
---|
| 1958 | c west |
---|
| 1959 | d0 = max(0.,qtmp(j,i-1)) |
---|
| 1960 | d1 = min(-qtmp(j,i),d0) |
---|
| 1961 | qtmp(j,i-1) = qtmp(j,i-1) - d1 |
---|
| 1962 | qtmp(j,i) = qtmp(j,i) + d1 |
---|
| 1963 | c east |
---|
| 1964 | d0 = max(0.,qtmp(j,1)) |
---|
| 1965 | d2 = min(-qtmp(j,i),d0) |
---|
| 1966 | qtmp(j,1) = qtmp(j,1) - d2 |
---|
| 1967 | c |
---|
| 1968 | qtmp(j,i) = qtmp(j,i) + d2 + tiny |
---|
| 1969 | endif |
---|
| 1970 | 75 continue |
---|
| 1971 | C |
---|
| 1972 | if(ipx.ne.0) then |
---|
| 1973 | do 85 j=j1,j2 |
---|
| 1974 | do 85 i=1,imr |
---|
| 1975 | 85 q(i,j) = qtmp(j,i) |
---|
| 1976 | else |
---|
| 1977 | C |
---|
| 1978 | C Poles. |
---|
| 1979 | if(q(1,1).lt.0. or. q(1,JNP).lt.0.) ipx = 1 |
---|
| 1980 | endif |
---|
| 1981 | return |
---|
| 1982 | end |
---|
| 1983 | C |
---|
| 1984 | subroutine zflip(q,im,km,nc) |
---|
| 1985 | C This routine flip the array q (in the vertical). |
---|
| 1986 | real q(im,km,nc) |
---|
| 1987 | C local dynamic array |
---|
| 1988 | real qtmp(im,km) |
---|
| 1989 | C |
---|
| 1990 | do 4000 IC = 1, nc |
---|
| 1991 | C |
---|
| 1992 | do 1000 k=1,km |
---|
| 1993 | do 1000 i=1,im |
---|
| 1994 | qtmp(i,k) = q(i,km+1-k,IC) |
---|
| 1995 | 1000 continue |
---|
| 1996 | C |
---|
| 1997 | do 2000 i=1,im*km |
---|
| 1998 | 2000 q(i,1,IC) = qtmp(i,1) |
---|
| 1999 | 4000 continue |
---|
| 2000 | return |
---|
| 2001 | end |
---|